/* Statement translation -- generate GCC trees from gfc_code. Copyright (C) 2002-2020 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 . */ #include "config.h" #include "system.h" #include "coretypes.h" #include "options.h" #include "tree.h" #include "gfortran.h" #include "trans.h" #include "stringpool.h" #include "fold-const.h" #include "trans-stmt.h" #include "trans-types.h" #include "trans-array.h" #include "trans-const.h" #include "dependency.h" typedef struct iter_info { tree var; tree start; tree end; tree step; struct iter_info *next; } iter_info; typedef struct forall_info { iter_info *this_loop; tree mask; tree maskindex; int nvar; tree size; struct forall_info *prev_nest; bool do_concurrent; } forall_info; static void gfc_trans_where_2 (gfc_code *, tree, bool, forall_info *, stmtblock_t *); /* Translate a F95 label number to a LABEL_EXPR. */ tree gfc_trans_label_here (gfc_code * code) { return build1_v (LABEL_EXPR, gfc_get_label_decl (code->here)); } /* Given a variable expression which has been ASSIGNed to, find the decl containing the auxiliary variables. For variables in common blocks this is a field_decl. */ void gfc_conv_label_variable (gfc_se * se, gfc_expr * expr) { gcc_assert (expr->symtree->n.sym->attr.assign == 1); gfc_conv_expr (se, expr); /* Deals with variable in common block. Get the field declaration. */ if (TREE_CODE (se->expr) == COMPONENT_REF) se->expr = TREE_OPERAND (se->expr, 1); /* Deals with dummy argument. Get the parameter declaration. */ else if (TREE_CODE (se->expr) == INDIRECT_REF) se->expr = TREE_OPERAND (se->expr, 0); } /* Translate a label assignment statement. */ tree gfc_trans_label_assign (gfc_code * code) { tree label_tree; gfc_se se; tree len; tree addr; tree len_tree; int label_len; /* Start a new block. */ gfc_init_se (&se, NULL); gfc_start_block (&se.pre); gfc_conv_label_variable (&se, code->expr1); len = GFC_DECL_STRING_LEN (se.expr); addr = GFC_DECL_ASSIGN_ADDR (se.expr); label_tree = gfc_get_label_decl (code->label1); if (code->label1->defined == ST_LABEL_TARGET || code->label1->defined == ST_LABEL_DO_TARGET) { label_tree = gfc_build_addr_expr (pvoid_type_node, label_tree); len_tree = build_int_cst (gfc_charlen_type_node, -1); } else { gfc_expr *format = code->label1->format; label_len = format->value.character.length; len_tree = build_int_cst (gfc_charlen_type_node, label_len); label_tree = gfc_build_wide_string_const (format->ts.kind, label_len + 1, format->value.character.string); label_tree = gfc_build_addr_expr (pvoid_type_node, label_tree); } gfc_add_modify (&se.pre, len, fold_convert (TREE_TYPE (len), len_tree)); gfc_add_modify (&se.pre, addr, label_tree); return gfc_finish_block (&se.pre); } /* Translate a GOTO statement. */ tree gfc_trans_goto (gfc_code * code) { locus loc = code->loc; tree assigned_goto; tree target; tree tmp; gfc_se se; if (code->label1 != NULL) return build1_v (GOTO_EXPR, gfc_get_label_decl (code->label1)); /* ASSIGNED GOTO. */ gfc_init_se (&se, NULL); gfc_start_block (&se.pre); gfc_conv_label_variable (&se, code->expr1); tmp = GFC_DECL_STRING_LEN (se.expr); tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, build_int_cst (TREE_TYPE (tmp), -1)); gfc_trans_runtime_check (true, false, tmp, &se.pre, &loc, "Assigned label is not a target label"); assigned_goto = GFC_DECL_ASSIGN_ADDR (se.expr); /* We're going to ignore a label list. It does not really change the statement's semantics (because it is just a further restriction on what's legal code); before, we were comparing label addresses here, but that's a very fragile business and may break with optimization. So just ignore it. */ target = fold_build1_loc (input_location, GOTO_EXPR, void_type_node, assigned_goto); gfc_add_expr_to_block (&se.pre, target); return gfc_finish_block (&se.pre); } /* Translate an ENTRY statement. Just adds a label for this entry point. */ tree gfc_trans_entry (gfc_code * code) { return build1_v (LABEL_EXPR, code->ext.entry->label); } /* Replace a gfc_ss structure by another both in the gfc_se struct and the gfc_loopinfo struct. This is used in gfc_conv_elemental_dependencies to replace a variable ss by the corresponding temporary. */ static void replace_ss (gfc_se *se, gfc_ss *old_ss, gfc_ss *new_ss) { gfc_ss **sess, **loopss; /* The old_ss is a ss for a single variable. */ gcc_assert (old_ss->info->type == GFC_SS_SECTION); for (sess = &(se->ss); *sess != gfc_ss_terminator; sess = &((*sess)->next)) if (*sess == old_ss) break; gcc_assert (*sess != gfc_ss_terminator); *sess = new_ss; new_ss->next = old_ss->next; for (loopss = &(se->loop->ss); *loopss != gfc_ss_terminator; loopss = &((*loopss)->loop_chain)) if (*loopss == old_ss) break; gcc_assert (*loopss != gfc_ss_terminator); *loopss = new_ss; new_ss->loop_chain = old_ss->loop_chain; new_ss->loop = old_ss->loop; gfc_free_ss (old_ss); } /* Check for dependencies between INTENT(IN) and INTENT(OUT) arguments of elemental subroutines. Make temporaries for output arguments if any such dependencies are found. Output arguments are chosen because internal_unpack can be used, as is, to copy the result back to the variable. */ static void gfc_conv_elemental_dependencies (gfc_se * se, gfc_se * loopse, gfc_symbol * sym, gfc_actual_arglist * arg, gfc_dep_check check_variable) { gfc_actual_arglist *arg0; gfc_expr *e; gfc_formal_arglist *formal; gfc_se parmse; gfc_ss *ss; gfc_symbol *fsym; tree data; tree size; tree tmp; if (loopse->ss == NULL) return; ss = loopse->ss; arg0 = arg; formal = gfc_sym_get_dummy_args (sym); /* Loop over all the arguments testing for dependencies. */ for (; arg != NULL; arg = arg->next, formal = formal ? formal->next : NULL) { e = arg->expr; if (e == NULL) continue; /* Obtain the info structure for the current argument. */ for (ss = loopse->ss; ss && ss != gfc_ss_terminator; ss = ss->next) if (ss->info->expr == e) break; /* If there is a dependency, create a temporary and use it instead of the variable. */ fsym = formal ? formal->sym : NULL; if (e->expr_type == EXPR_VARIABLE && e->rank && fsym && fsym->attr.intent != INTENT_IN && gfc_check_fncall_dependency (e, fsym->attr.intent, sym, arg0, check_variable)) { tree initial, temptype; stmtblock_t temp_post; gfc_ss *tmp_ss; tmp_ss = gfc_get_array_ss (gfc_ss_terminator, NULL, ss->dimen, GFC_SS_SECTION); gfc_mark_ss_chain_used (tmp_ss, 1); tmp_ss->info->expr = ss->info->expr; replace_ss (loopse, ss, tmp_ss); /* Obtain the argument descriptor for unpacking. */ gfc_init_se (&parmse, NULL); parmse.want_pointer = 1; gfc_conv_expr_descriptor (&parmse, e); gfc_add_block_to_block (&se->pre, &parmse.pre); /* If we've got INTENT(INOUT) or a derived type with INTENT(OUT), initialize the array temporary with a copy of the values. */ if (fsym->attr.intent == INTENT_INOUT || (fsym->ts.type ==BT_DERIVED && fsym->attr.intent == INTENT_OUT)) initial = parmse.expr; /* For class expressions, we always initialize with the copy of the values. */ else if (e->ts.type == BT_CLASS) initial = parmse.expr; else initial = NULL_TREE; if (e->ts.type != BT_CLASS) { /* Find the type of the temporary to create; we don't use the type of e itself as this breaks for subcomponent-references in e (where the type of e is that of the final reference, but parmse.expr's type corresponds to the full derived-type). */ /* TODO: Fix this somehow so we don't need a temporary of the whole array but instead only the components referenced. */ temptype = TREE_TYPE (parmse.expr); /* Pointer to descriptor. */ gcc_assert (TREE_CODE (temptype) == POINTER_TYPE); temptype = TREE_TYPE (temptype); temptype = gfc_get_element_type (temptype); } else /* For class arrays signal that the size of the dynamic type has to be obtained from the vtable, using the 'initial' expression. */ temptype = NULL_TREE; /* Generate the temporary. Cleaning up the temporary should be the very last thing done, so we add the code to a new block and add it to se->post as last instructions. */ size = gfc_create_var (gfc_array_index_type, NULL); data = gfc_create_var (pvoid_type_node, NULL); gfc_init_block (&temp_post); tmp = gfc_trans_create_temp_array (&se->pre, &temp_post, tmp_ss, temptype, initial, false, true, false, &arg->expr->where); gfc_add_modify (&se->pre, size, tmp); tmp = fold_convert (pvoid_type_node, tmp_ss->info->data.array.data); gfc_add_modify (&se->pre, data, tmp); /* Update other ss' delta. */ gfc_set_delta (loopse->loop); /* Copy the result back using unpack..... */ if (e->ts.type != BT_CLASS) tmp = build_call_expr_loc (input_location, gfor_fndecl_in_unpack, 2, parmse.expr, data); else { /* ... except for class results where the copy is unconditional. */ tmp = build_fold_indirect_ref_loc (input_location, parmse.expr); tmp = gfc_conv_descriptor_data_get (tmp); tmp = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_MEMCPY), 3, tmp, data, fold_convert (size_type_node, size)); } gfc_add_expr_to_block (&se->post, tmp); /* parmse.pre is already added above. */ gfc_add_block_to_block (&se->post, &parmse.post); gfc_add_block_to_block (&se->post, &temp_post); } } } /* Get the interface symbol for the procedure corresponding to the given call. We can't get the procedure symbol directly as we have to handle the case of (deferred) type-bound procedures. */ static gfc_symbol * get_proc_ifc_for_call (gfc_code *c) { gfc_symbol *sym; gcc_assert (c->op == EXEC_ASSIGN_CALL || c->op == EXEC_CALL); sym = gfc_get_proc_ifc_for_expr (c->expr1); /* Fall back/last resort try. */ if (sym == NULL) sym = c->resolved_sym; return sym; } /* Translate the CALL statement. Builds a call to an F95 subroutine. */ tree gfc_trans_call (gfc_code * code, bool dependency_check, tree mask, tree count1, bool invert) { gfc_se se; gfc_ss * ss; int has_alternate_specifier; gfc_dep_check check_variable; tree index = NULL_TREE; tree maskexpr = NULL_TREE; tree tmp; /* A CALL starts a new block because the actual arguments may have to be evaluated first. */ gfc_init_se (&se, NULL); gfc_start_block (&se.pre); gcc_assert (code->resolved_sym); ss = gfc_ss_terminator; if (code->resolved_sym->attr.elemental) ss = gfc_walk_elemental_function_args (ss, code->ext.actual, get_proc_ifc_for_call (code), GFC_SS_REFERENCE); /* Is not an elemental subroutine call with array valued arguments. */ if (ss == gfc_ss_terminator) { /* Translate the call. */ has_alternate_specifier = gfc_conv_procedure_call (&se, code->resolved_sym, code->ext.actual, code->expr1, NULL); /* A subroutine without side-effect, by definition, does nothing! */ TREE_SIDE_EFFECTS (se.expr) = 1; /* Chain the pieces together and return the block. */ if (has_alternate_specifier) { gfc_code *select_code; gfc_symbol *sym; select_code = code->next; gcc_assert(select_code->op == EXEC_SELECT); sym = select_code->expr1->symtree->n.sym; se.expr = convert (gfc_typenode_for_spec (&sym->ts), se.expr); if (sym->backend_decl == NULL) sym->backend_decl = gfc_get_symbol_decl (sym); gfc_add_modify (&se.pre, sym->backend_decl, se.expr); } else gfc_add_expr_to_block (&se.pre, se.expr); gfc_add_block_to_block (&se.pre, &se.post); } else { /* An elemental subroutine call with array valued arguments has to be scalarized. */ gfc_loopinfo loop; stmtblock_t body; stmtblock_t block; gfc_se loopse; gfc_se depse; /* gfc_walk_elemental_function_args renders the ss chain in the reverse order to the actual argument order. */ ss = gfc_reverse_ss (ss); /* Initialize the loop. */ gfc_init_se (&loopse, NULL); gfc_init_loopinfo (&loop); gfc_add_ss_to_loop (&loop, ss); gfc_conv_ss_startstride (&loop); /* TODO: gfc_conv_loop_setup generates a temporary for vector subscripts. This could be prevented in the elemental case as temporaries are handled separatedly (below in gfc_conv_elemental_dependencies). */ if (code->expr1) gfc_conv_loop_setup (&loop, &code->expr1->where); else gfc_conv_loop_setup (&loop, &code->loc); gfc_mark_ss_chain_used (ss, 1); /* Convert the arguments, checking for dependencies. */ gfc_copy_loopinfo_to_se (&loopse, &loop); loopse.ss = ss; /* For operator assignment, do dependency checking. */ if (dependency_check) check_variable = ELEM_CHECK_VARIABLE; else check_variable = ELEM_DONT_CHECK_VARIABLE; gfc_init_se (&depse, NULL); gfc_conv_elemental_dependencies (&depse, &loopse, code->resolved_sym, code->ext.actual, check_variable); gfc_add_block_to_block (&loop.pre, &depse.pre); gfc_add_block_to_block (&loop.post, &depse.post); /* Generate the loop body. */ gfc_start_scalarized_body (&loop, &body); gfc_init_block (&block); if (mask && count1) { /* Form the mask expression according to the mask. */ index = count1; maskexpr = gfc_build_array_ref (mask, index, NULL); if (invert) maskexpr = fold_build1_loc (input_location, TRUTH_NOT_EXPR, TREE_TYPE (maskexpr), maskexpr); } /* Add the subroutine call to the block. */ gfc_conv_procedure_call (&loopse, code->resolved_sym, code->ext.actual, code->expr1, NULL); if (mask && count1) { tmp = build3_v (COND_EXPR, maskexpr, loopse.expr, build_empty_stmt (input_location)); gfc_add_expr_to_block (&loopse.pre, tmp); tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count1, gfc_index_one_node); gfc_add_modify (&loopse.pre, count1, tmp); } else gfc_add_expr_to_block (&loopse.pre, loopse.expr); gfc_add_block_to_block (&block, &loopse.pre); gfc_add_block_to_block (&block, &loopse.post); /* Finish up the loop block and the loop. */ gfc_add_expr_to_block (&body, gfc_finish_block (&block)); 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_add_block_to_block (&se.pre, &se.post); gfc_cleanup_loop (&loop); } return gfc_finish_block (&se.pre); } /* Translate the RETURN statement. */ tree gfc_trans_return (gfc_code * code) { if (code->expr1) { gfc_se se; tree tmp; tree result; /* If code->expr is not NULL, this return statement must appear in a subroutine and current_fake_result_decl has already been generated. */ result = gfc_get_fake_result_decl (NULL, 0); if (!result) { gfc_warning (0, "An alternate return at %L without a * dummy argument", &code->expr1->where); return gfc_generate_return (); } /* Start a new block for this statement. */ gfc_init_se (&se, NULL); gfc_start_block (&se.pre); gfc_conv_expr (&se, code->expr1); /* Note that the actually returned expression is a simple value and does not depend on any pointers or such; thus we can clean-up with se.post before returning. */ tmp = fold_build2_loc (input_location, MODIFY_EXPR, TREE_TYPE (result), result, fold_convert (TREE_TYPE (result), se.expr)); gfc_add_expr_to_block (&se.pre, tmp); gfc_add_block_to_block (&se.pre, &se.post); tmp = gfc_generate_return (); gfc_add_expr_to_block (&se.pre, tmp); return gfc_finish_block (&se.pre); } return gfc_generate_return (); } /* Translate the PAUSE statement. We have to translate this statement to a runtime library call. */ tree gfc_trans_pause (gfc_code * code) { tree gfc_int8_type_node = gfc_get_int_type (8); gfc_se se; tree tmp; /* Start a new block for this statement. */ gfc_init_se (&se, NULL); gfc_start_block (&se.pre); if (code->expr1 == NULL) { tmp = build_int_cst (size_type_node, 0); tmp = build_call_expr_loc (input_location, gfor_fndecl_pause_string, 2, build_int_cst (pchar_type_node, 0), tmp); } else if (code->expr1->ts.type == BT_INTEGER) { gfc_conv_expr (&se, code->expr1); tmp = build_call_expr_loc (input_location, gfor_fndecl_pause_numeric, 1, fold_convert (gfc_int8_type_node, se.expr)); } else { gfc_conv_expr_reference (&se, code->expr1); tmp = build_call_expr_loc (input_location, gfor_fndecl_pause_string, 2, se.expr, fold_convert (size_type_node, se.string_length)); } gfc_add_expr_to_block (&se.pre, tmp); gfc_add_block_to_block (&se.pre, &se.post); return gfc_finish_block (&se.pre); } /* Translate the STOP statement. We have to translate this statement to a runtime library call. */ tree gfc_trans_stop (gfc_code *code, bool error_stop) { gfc_se se; tree tmp; /* Start a new block for this statement. */ gfc_init_se (&se, NULL); gfc_start_block (&se.pre); if (code->expr1 == NULL) { tmp = build_int_cst (size_type_node, 0); tmp = build_call_expr_loc (input_location, error_stop ? (flag_coarray == GFC_FCOARRAY_LIB ? gfor_fndecl_caf_error_stop_str : gfor_fndecl_error_stop_string) : (flag_coarray == GFC_FCOARRAY_LIB ? gfor_fndecl_caf_stop_str : gfor_fndecl_stop_string), 3, build_int_cst (pchar_type_node, 0), tmp, boolean_false_node); } else if (code->expr1->ts.type == BT_INTEGER) { gfc_conv_expr (&se, code->expr1); tmp = build_call_expr_loc (input_location, error_stop ? (flag_coarray == GFC_FCOARRAY_LIB ? gfor_fndecl_caf_error_stop : gfor_fndecl_error_stop_numeric) : (flag_coarray == GFC_FCOARRAY_LIB ? gfor_fndecl_caf_stop_numeric : gfor_fndecl_stop_numeric), 2, fold_convert (integer_type_node, se.expr), boolean_false_node); } else { gfc_conv_expr_reference (&se, code->expr1); tmp = build_call_expr_loc (input_location, error_stop ? (flag_coarray == GFC_FCOARRAY_LIB ? gfor_fndecl_caf_error_stop_str : gfor_fndecl_error_stop_string) : (flag_coarray == GFC_FCOARRAY_LIB ? gfor_fndecl_caf_stop_str : gfor_fndecl_stop_string), 3, se.expr, fold_convert (size_type_node, se.string_length), boolean_false_node); } gfc_add_expr_to_block (&se.pre, tmp); gfc_add_block_to_block (&se.pre, &se.post); return gfc_finish_block (&se.pre); } /* Translate the FAIL IMAGE statement. */ tree gfc_trans_fail_image (gfc_code *code ATTRIBUTE_UNUSED) { if (flag_coarray == GFC_FCOARRAY_LIB) return build_call_expr_loc (input_location, gfor_fndecl_caf_fail_image, 1, build_int_cst (pchar_type_node, 0)); else { const char *name = gfc_get_string (PREFIX ("exit_i%d"), 4); gfc_symbol *exsym = gfc_get_intrinsic_sub_symbol (name); tree tmp = gfc_get_symbol_decl (exsym); return build_call_expr_loc (input_location, tmp, 1, integer_zero_node); } } /* Translate the FORM TEAM statement. */ tree gfc_trans_form_team (gfc_code *code) { if (flag_coarray == GFC_FCOARRAY_LIB) { gfc_se se; gfc_se argse1, argse2; tree team_id, team_type, tmp; gfc_init_se (&se, NULL); gfc_init_se (&argse1, NULL); gfc_init_se (&argse2, NULL); gfc_start_block (&se.pre); gfc_conv_expr_val (&argse1, code->expr1); gfc_conv_expr_val (&argse2, code->expr2); team_id = fold_convert (integer_type_node, argse1.expr); team_type = gfc_build_addr_expr (ppvoid_type_node, argse2.expr); gfc_add_block_to_block (&se.pre, &argse1.pre); gfc_add_block_to_block (&se.pre, &argse2.pre); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_form_team, 3, team_id, team_type, build_int_cst (integer_type_node, 0)); gfc_add_expr_to_block (&se.pre, tmp); gfc_add_block_to_block (&se.pre, &argse1.post); gfc_add_block_to_block (&se.pre, &argse2.post); return gfc_finish_block (&se.pre); } else { const char *name = gfc_get_string (PREFIX ("exit_i%d"), 4); gfc_symbol *exsym = gfc_get_intrinsic_sub_symbol (name); tree tmp = gfc_get_symbol_decl (exsym); return build_call_expr_loc (input_location, tmp, 1, integer_zero_node); } } /* Translate the CHANGE TEAM statement. */ tree gfc_trans_change_team (gfc_code *code) { if (flag_coarray == GFC_FCOARRAY_LIB) { gfc_se argse; tree team_type, tmp; gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr1); team_type = gfc_build_addr_expr (ppvoid_type_node, argse.expr); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_change_team, 2, team_type, build_int_cst (integer_type_node, 0)); gfc_add_expr_to_block (&argse.pre, tmp); gfc_add_block_to_block (&argse.pre, &argse.post); return gfc_finish_block (&argse.pre); } else { const char *name = gfc_get_string (PREFIX ("exit_i%d"), 4); gfc_symbol *exsym = gfc_get_intrinsic_sub_symbol (name); tree tmp = gfc_get_symbol_decl (exsym); return build_call_expr_loc (input_location, tmp, 1, integer_zero_node); } } /* Translate the END TEAM statement. */ tree gfc_trans_end_team (gfc_code *code ATTRIBUTE_UNUSED) { if (flag_coarray == GFC_FCOARRAY_LIB) { return build_call_expr_loc (input_location, gfor_fndecl_caf_end_team, 1, build_int_cst (pchar_type_node, 0)); } else { const char *name = gfc_get_string (PREFIX ("exit_i%d"), 4); gfc_symbol *exsym = gfc_get_intrinsic_sub_symbol (name); tree tmp = gfc_get_symbol_decl (exsym); return build_call_expr_loc (input_location, tmp, 1, integer_zero_node); } } /* Translate the SYNC TEAM statement. */ tree gfc_trans_sync_team (gfc_code *code) { if (flag_coarray == GFC_FCOARRAY_LIB) { gfc_se argse; tree team_type, tmp; gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr1); team_type = gfc_build_addr_expr (ppvoid_type_node, argse.expr); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_team, 2, team_type, build_int_cst (integer_type_node, 0)); gfc_add_expr_to_block (&argse.pre, tmp); gfc_add_block_to_block (&argse.pre, &argse.post); return gfc_finish_block (&argse.pre); } else { const char *name = gfc_get_string (PREFIX ("exit_i%d"), 4); gfc_symbol *exsym = gfc_get_intrinsic_sub_symbol (name); tree tmp = gfc_get_symbol_decl (exsym); return build_call_expr_loc (input_location, tmp, 1, integer_zero_node); } } tree gfc_trans_lock_unlock (gfc_code *code, gfc_exec_op op) { gfc_se se, argse; tree stat = NULL_TREE, stat2 = NULL_TREE; tree lock_acquired = NULL_TREE, lock_acquired2 = NULL_TREE; /* Short cut: For single images without STAT= or LOCK_ACQUIRED return early. (ERRMSG= is always untouched for -fcoarray=single.) */ if (!code->expr2 && !code->expr4 && flag_coarray != GFC_FCOARRAY_LIB) return NULL_TREE; if (code->expr2) { gcc_assert (code->expr2->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr2); stat = argse.expr; } else if (flag_coarray == GFC_FCOARRAY_LIB) stat = null_pointer_node; if (code->expr4) { gcc_assert (code->expr4->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr4); lock_acquired = argse.expr; } else if (flag_coarray == GFC_FCOARRAY_LIB) lock_acquired = null_pointer_node; gfc_start_block (&se.pre); if (flag_coarray == GFC_FCOARRAY_LIB) { tree tmp, token, image_index, errmsg, errmsg_len; tree index = build_zero_cst (gfc_array_index_type); tree caf_decl = gfc_get_tree_for_caf_expr (code->expr1); if (code->expr1->symtree->n.sym->ts.type != BT_DERIVED || code->expr1->symtree->n.sym->ts.u.derived->from_intmod != INTMOD_ISO_FORTRAN_ENV || code->expr1->symtree->n.sym->ts.u.derived->intmod_sym_id != ISOFORTRAN_LOCK_TYPE) { gfc_error ("Sorry, the lock component of derived type at %L is not " "yet supported", &code->expr1->where); return NULL_TREE; } gfc_get_caf_token_offset (&se, &token, NULL, caf_decl, NULL_TREE, code->expr1); if (gfc_is_coindexed (code->expr1)) image_index = gfc_caf_get_image_index (&se.pre, code->expr1, caf_decl); else image_index = integer_zero_node; /* For arrays, obtain the array index. */ if (gfc_expr_attr (code->expr1).dimension) { tree desc, tmp, extent, lbound, ubound; gfc_array_ref *ar, ar2; int i; /* TODO: Extend this, once DT components are supported. */ ar = &code->expr1->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, code->expr1); 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); } } } /* errmsg. */ if (code->expr3) { gfc_init_se (&argse, NULL); argse.want_pointer = 1; gfc_conv_expr (&argse, code->expr3); gfc_add_block_to_block (&se.pre, &argse.pre); 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); } if (stat != null_pointer_node && TREE_TYPE (stat) != integer_type_node) { stat2 = stat; stat = gfc_create_var (integer_type_node, "stat"); } if (lock_acquired != null_pointer_node && TREE_TYPE (lock_acquired) != integer_type_node) { lock_acquired2 = lock_acquired; lock_acquired = gfc_create_var (integer_type_node, "acquired"); } index = fold_convert (size_type_node, index); if (op == EXEC_LOCK) tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_lock, 7, token, index, image_index, lock_acquired != null_pointer_node ? gfc_build_addr_expr (NULL, lock_acquired) : lock_acquired, stat != null_pointer_node ? gfc_build_addr_expr (NULL, stat) : stat, errmsg, errmsg_len); else tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_unlock, 6, token, index, image_index, stat != null_pointer_node ? gfc_build_addr_expr (NULL, stat) : stat, errmsg, errmsg_len); gfc_add_expr_to_block (&se.pre, tmp); /* 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); if (stat2 != NULL_TREE) gfc_add_modify (&se.pre, stat2, fold_convert (TREE_TYPE (stat2), stat)); if (lock_acquired2 != NULL_TREE) gfc_add_modify (&se.pre, lock_acquired2, fold_convert (TREE_TYPE (lock_acquired2), lock_acquired)); return gfc_finish_block (&se.pre); } if (stat != NULL_TREE) gfc_add_modify (&se.pre, stat, build_int_cst (TREE_TYPE (stat), 0)); if (lock_acquired != NULL_TREE) gfc_add_modify (&se.pre, lock_acquired, fold_convert (TREE_TYPE (lock_acquired), boolean_true_node)); return gfc_finish_block (&se.pre); } tree gfc_trans_event_post_wait (gfc_code *code, gfc_exec_op op) { gfc_se se, argse; tree stat = NULL_TREE, stat2 = NULL_TREE; tree until_count = NULL_TREE; if (code->expr2) { gcc_assert (code->expr2->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr2); stat = argse.expr; } else if (flag_coarray == GFC_FCOARRAY_LIB) stat = null_pointer_node; if (code->expr4) { gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr4); until_count = fold_convert (integer_type_node, argse.expr); } else until_count = integer_one_node; if (flag_coarray != GFC_FCOARRAY_LIB) { gfc_start_block (&se.pre); gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr1); if (op == EXEC_EVENT_POST) gfc_add_modify (&se.pre, argse.expr, fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (argse.expr), argse.expr, build_int_cst (TREE_TYPE (argse.expr), 1))); else gfc_add_modify (&se.pre, argse.expr, fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (argse.expr), argse.expr, fold_convert (TREE_TYPE (argse.expr), until_count))); if (stat != NULL_TREE) gfc_add_modify (&se.pre, stat, build_int_cst (TREE_TYPE (stat), 0)); return gfc_finish_block (&se.pre); } gfc_start_block (&se.pre); tree tmp, token, image_index, errmsg, errmsg_len; tree index = build_zero_cst (gfc_array_index_type); tree caf_decl = gfc_get_tree_for_caf_expr (code->expr1); if (code->expr1->symtree->n.sym->ts.type != BT_DERIVED || code->expr1->symtree->n.sym->ts.u.derived->from_intmod != INTMOD_ISO_FORTRAN_ENV || code->expr1->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", &code->expr1->where); return NULL_TREE; } gfc_init_se (&argse, NULL); gfc_get_caf_token_offset (&argse, &token, NULL, caf_decl, NULL_TREE, code->expr1); gfc_add_block_to_block (&se.pre, &argse.pre); if (gfc_is_coindexed (code->expr1)) image_index = gfc_caf_get_image_index (&se.pre, code->expr1, caf_decl); else image_index = integer_zero_node; /* For arrays, obtain the array index. */ if (gfc_expr_attr (code->expr1).dimension) { tree desc, tmp, extent, lbound, ubound; gfc_array_ref *ar, ar2; int i; /* TODO: Extend this, once DT components are supported. */ ar = &code->expr1->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, code->expr1); 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); } } } /* errmsg. */ if (code->expr3) { gfc_init_se (&argse, NULL); argse.want_pointer = 1; gfc_conv_expr (&argse, code->expr3); gfc_add_block_to_block (&se.pre, &argse.pre); 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); } 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); if (op == EXEC_EVENT_POST) tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_event_post, 6, token, index, image_index, stat != null_pointer_node ? gfc_build_addr_expr (NULL, stat) : stat, errmsg, errmsg_len); else tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_event_wait, 6, token, index, until_count, stat != null_pointer_node ? gfc_build_addr_expr (NULL, stat) : stat, errmsg, errmsg_len); gfc_add_expr_to_block (&se.pre, tmp); /* 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); if (stat2 != NULL_TREE) gfc_add_modify (&se.pre, stat2, fold_convert (TREE_TYPE (stat2), stat)); return gfc_finish_block (&se.pre); } tree gfc_trans_sync (gfc_code *code, gfc_exec_op type) { gfc_se se, argse; tree tmp; tree images = NULL_TREE, stat = NULL_TREE, errmsg = NULL_TREE, errmsglen = NULL_TREE; /* Short cut: For single images without bound checking or without STAT=, return early. (ERRMSG= is always untouched for -fcoarray=single.) */ if (!code->expr2 && !(gfc_option.rtcheck & GFC_RTCHECK_BOUNDS) && flag_coarray != GFC_FCOARRAY_LIB) return NULL_TREE; gfc_init_se (&se, NULL); gfc_start_block (&se.pre); if (code->expr1 && code->expr1->rank == 0) { gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr1); images = argse.expr; } if (code->expr2) { gcc_assert (code->expr2->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->expr2); stat = argse.expr; } else stat = null_pointer_node; if (code->expr3 && flag_coarray == GFC_FCOARRAY_LIB) { gcc_assert (code->expr3->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); argse.want_pointer = 1; gfc_conv_expr (&argse, code->expr3); gfc_conv_string_parameter (&argse); errmsg = gfc_build_addr_expr (NULL, argse.expr); errmsglen = fold_convert (size_type_node, argse.string_length); } else if (flag_coarray == GFC_FCOARRAY_LIB) { errmsg = null_pointer_node; errmsglen = build_int_cst (size_type_node, 0); } /* Check SYNC IMAGES(imageset) for valid image index. FIXME: Add a check for image-set arrays. */ if (code->expr1 && (gfc_option.rtcheck & GFC_RTCHECK_BOUNDS) && code->expr1->rank == 0) { tree images2 = fold_convert (integer_type_node, images); tree cond; if (flag_coarray != GFC_FCOARRAY_LIB) cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, images, build_int_cst (TREE_TYPE (images), 1)); else { tree cond2; tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_num_images, 2, integer_zero_node, build_int_cst (integer_type_node, -1)); cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, images2, tmp); cond2 = fold_build2_loc (input_location, LT_EXPR, logical_type_node, images, build_int_cst (TREE_TYPE (images), 1)); cond = fold_build2_loc (input_location, TRUTH_OR_EXPR, logical_type_node, cond, cond2); } gfc_trans_runtime_check (true, false, cond, &se.pre, &code->expr1->where, "Invalid image number " "%d in SYNC IMAGES", images2); } /* Per F2008, 8.5.1, a SYNC MEMORY is implied by calling the image control statements SYNC IMAGES and SYNC ALL. */ if (flag_coarray == GFC_FCOARRAY_LIB) { 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); } if (flag_coarray != GFC_FCOARRAY_LIB) { /* Set STAT to zero. */ if (code->expr2) gfc_add_modify (&se.pre, stat, build_int_cst (TREE_TYPE (stat), 0)); } else if (type == EXEC_SYNC_ALL || type == EXEC_SYNC_MEMORY) { /* SYNC ALL => stat == null_pointer_node SYNC ALL(stat=s) => stat has an integer type If "stat" has the wrong integer type, use a temp variable of the right type and later cast the result back into "stat". */ if (stat == null_pointer_node || TREE_TYPE (stat) == integer_type_node) { if (TREE_TYPE (stat) == integer_type_node) stat = gfc_build_addr_expr (NULL, stat); if(type == EXEC_SYNC_MEMORY) tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_memory, 3, stat, errmsg, errmsglen); else tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_all, 3, stat, errmsg, errmsglen); gfc_add_expr_to_block (&se.pre, tmp); } else { tree tmp_stat = gfc_create_var (integer_type_node, "stat"); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_all, 3, gfc_build_addr_expr (NULL, tmp_stat), errmsg, errmsglen); gfc_add_expr_to_block (&se.pre, tmp); gfc_add_modify (&se.pre, stat, fold_convert (TREE_TYPE (stat), tmp_stat)); } } else { tree len; gcc_assert (type == EXEC_SYNC_IMAGES); if (!code->expr1) { len = build_int_cst (integer_type_node, -1); images = null_pointer_node; } else if (code->expr1->rank == 0) { len = build_int_cst (integer_type_node, 1); images = gfc_build_addr_expr (NULL_TREE, images); } else { /* FIXME. */ if (code->expr1->ts.kind != gfc_c_int_kind) gfc_fatal_error ("Sorry, only support for integer kind %d " "implemented for image-set at %L", gfc_c_int_kind, &code->expr1->where); gfc_conv_array_parameter (&se, code->expr1, true, NULL, NULL, &len); images = se.expr; tmp = gfc_typenode_for_spec (&code->expr1->ts); if (GFC_ARRAY_TYPE_P (tmp) || GFC_DESCRIPTOR_TYPE_P (tmp)) tmp = gfc_get_element_type (tmp); len = fold_build2_loc (input_location, TRUNC_DIV_EXPR, TREE_TYPE (len), len, fold_convert (TREE_TYPE (len), TYPE_SIZE_UNIT (tmp))); len = fold_convert (integer_type_node, len); } /* SYNC IMAGES(imgs) => stat == null_pointer_node SYNC IMAGES(imgs,stat=s) => stat has an integer type If "stat" has the wrong integer type, use a temp variable of the right type and later cast the result back into "stat". */ if (stat == null_pointer_node || TREE_TYPE (stat) == integer_type_node) { if (TREE_TYPE (stat) == integer_type_node) stat = gfc_build_addr_expr (NULL, stat); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_images, 5, fold_convert (integer_type_node, len), images, stat, errmsg, errmsglen); gfc_add_expr_to_block (&se.pre, tmp); } else { tree tmp_stat = gfc_create_var (integer_type_node, "stat"); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_images, 5, fold_convert (integer_type_node, len), images, gfc_build_addr_expr (NULL, tmp_stat), errmsg, errmsglen); gfc_add_expr_to_block (&se.pre, tmp); gfc_add_modify (&se.pre, stat, fold_convert (TREE_TYPE (stat), tmp_stat)); } } return gfc_finish_block (&se.pre); } /* Generate GENERIC for the IF construct. This function also deals with the simple IF statement, because the front end translates the IF statement into an IF construct. We translate: IF (cond) THEN then_clause ELSEIF (cond2) elseif_clause ELSE else_clause ENDIF into: pre_cond_s; if (cond_s) { then_clause; } else { pre_cond_s if (cond_s) { elseif_clause } else { else_clause; } } where COND_S is the simplified version of the predicate. PRE_COND_S are the pre side-effects produced by the translation of the conditional. We need to build the chain recursively otherwise we run into problems with folding incomplete statements. */ static tree gfc_trans_if_1 (gfc_code * code) { gfc_se if_se; tree stmt, elsestmt; locus saved_loc; location_t loc; /* Check for an unconditional ELSE clause. */ if (!code->expr1) return gfc_trans_code (code->next); /* Initialize a statement builder for each block. Puts in NULL_TREEs. */ gfc_init_se (&if_se, NULL); gfc_start_block (&if_se.pre); /* Calculate the IF condition expression. */ if (code->expr1->where.lb) { gfc_save_backend_locus (&saved_loc); gfc_set_backend_locus (&code->expr1->where); } gfc_conv_expr_val (&if_se, code->expr1); if (code->expr1->where.lb) gfc_restore_backend_locus (&saved_loc); /* Translate the THEN clause. */ stmt = gfc_trans_code (code->next); /* Translate the ELSE clause. */ if (code->block) elsestmt = gfc_trans_if_1 (code->block); else elsestmt = build_empty_stmt (input_location); /* Build the condition expression and add it to the condition block. */ loc = code->expr1->where.lb ? gfc_get_location (&code->expr1->where) : input_location; stmt = fold_build3_loc (loc, COND_EXPR, void_type_node, if_se.expr, stmt, elsestmt); gfc_add_expr_to_block (&if_se.pre, stmt); /* Finish off this statement. */ return gfc_finish_block (&if_se.pre); } tree gfc_trans_if (gfc_code * code) { stmtblock_t body; tree exit_label; /* Create exit label so it is available for trans'ing the body code. */ exit_label = gfc_build_label_decl (NULL_TREE); code->exit_label = exit_label; /* Translate the actual code in code->block. */ gfc_init_block (&body); gfc_add_expr_to_block (&body, gfc_trans_if_1 (code->block)); /* Add exit label. */ gfc_add_expr_to_block (&body, build1_v (LABEL_EXPR, exit_label)); return gfc_finish_block (&body); } /* Translate an arithmetic IF expression. IF (cond) label1, label2, label3 translates to if (cond <= 0) { if (cond < 0) goto label1; else // cond == 0 goto label2; } else // cond > 0 goto label3; An optimized version can be generated in case of equal labels. E.g., if label1 is equal to label2, we can translate it to if (cond <= 0) goto label1; else goto label3; */ tree gfc_trans_arithmetic_if (gfc_code * code) { gfc_se se; tree tmp; tree branch1; tree branch2; tree zero; /* Start a new block. */ gfc_init_se (&se, NULL); gfc_start_block (&se.pre); /* Pre-evaluate COND. */ gfc_conv_expr_val (&se, code->expr1); se.expr = gfc_evaluate_now (se.expr, &se.pre); /* Build something to compare with. */ zero = gfc_build_const (TREE_TYPE (se.expr), integer_zero_node); if (code->label1->value != code->label2->value) { /* If (cond < 0) take branch1 else take branch2. First build jumps to the COND .LT. 0 and the COND .EQ. 0 cases. */ branch1 = build1_v (GOTO_EXPR, gfc_get_label_decl (code->label1)); branch2 = build1_v (GOTO_EXPR, gfc_get_label_decl (code->label2)); if (code->label1->value != code->label3->value) tmp = fold_build2_loc (input_location, LT_EXPR, logical_type_node, se.expr, zero); else tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, se.expr, zero); branch1 = fold_build3_loc (input_location, COND_EXPR, void_type_node, tmp, branch1, branch2); } else branch1 = build1_v (GOTO_EXPR, gfc_get_label_decl (code->label1)); if (code->label1->value != code->label3->value && code->label2->value != code->label3->value) { /* if (cond <= 0) take branch1 else take branch2. */ branch2 = build1_v (GOTO_EXPR, gfc_get_label_decl (code->label3)); tmp = fold_build2_loc (input_location, LE_EXPR, logical_type_node, se.expr, zero); branch1 = fold_build3_loc (input_location, COND_EXPR, void_type_node, tmp, branch1, branch2); } /* Append the COND_EXPR to the evaluation of COND, and return. */ gfc_add_expr_to_block (&se.pre, branch1); return gfc_finish_block (&se.pre); } /* Translate a CRITICAL block. */ tree gfc_trans_critical (gfc_code *code) { stmtblock_t block; tree tmp, token = NULL_TREE; gfc_start_block (&block); if (flag_coarray == GFC_FCOARRAY_LIB) { tree zero_size = build_zero_cst (size_type_node); token = gfc_get_symbol_decl (code->resolved_sym); token = GFC_TYPE_ARRAY_CAF_TOKEN (TREE_TYPE (token)); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_lock, 7, token, zero_size, integer_one_node, null_pointer_node, null_pointer_node, null_pointer_node, zero_size); gfc_add_expr_to_block (&block, tmp); /* 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); } tmp = gfc_trans_code (code->block->next); gfc_add_expr_to_block (&block, tmp); if (flag_coarray == GFC_FCOARRAY_LIB) { tree zero_size = build_zero_cst (size_type_node); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_unlock, 6, token, zero_size, integer_one_node, null_pointer_node, null_pointer_node, zero_size); gfc_add_expr_to_block (&block, tmp); /* 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); } /* Return true, when the class has a _len component. */ static bool class_has_len_component (gfc_symbol *sym) { gfc_component *comp = sym->ts.u.derived->components; while (comp) { if (strcmp (comp->name, "_len") == 0) return true; comp = comp->next; } return false; } static void copy_descriptor (stmtblock_t *block, tree dst, tree src, int rank) { int n; tree dim; tree tmp; tree tmp2; tree size; tree offset; offset = gfc_index_zero_node; /* Use memcpy to copy the descriptor. The size is the minimum of the sizes of 'src' and 'dst'. This avoids a non-trivial conversion. */ tmp = TYPE_SIZE_UNIT (TREE_TYPE (src)); tmp2 = TYPE_SIZE_UNIT (TREE_TYPE (dst)); size = fold_build2_loc (input_location, MIN_EXPR, TREE_TYPE (tmp), tmp, tmp2); tmp = builtin_decl_explicit (BUILT_IN_MEMCPY); tmp = build_call_expr_loc (input_location, tmp, 3, gfc_build_addr_expr (NULL_TREE, dst), gfc_build_addr_expr (NULL_TREE, src), fold_convert (size_type_node, size)); gfc_add_expr_to_block (block, tmp); /* Set the offset correctly. */ for (n = 0; n < rank; n++) { dim = gfc_rank_cst[n]; tmp = gfc_conv_descriptor_lbound_get (src, dim); tmp2 = gfc_conv_descriptor_stride_get (src, dim); tmp = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (tmp), tmp, tmp2); offset = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (offset), offset, tmp); offset = gfc_evaluate_now (offset, block); } gfc_conv_descriptor_offset_set (block, dst, offset); } /* Do proper initialization for ASSOCIATE names. */ static void trans_associate_var (gfc_symbol *sym, gfc_wrapped_block *block) { gfc_expr *e; tree tmp; bool class_target; bool unlimited; tree desc; tree offset; tree dim; int n; tree charlen; bool need_len_assign; bool whole_array = true; gfc_ref *ref; gfc_symbol *sym2; gcc_assert (sym->assoc); e = sym->assoc->target; class_target = (e->expr_type == EXPR_VARIABLE) && (gfc_is_class_scalar_expr (e) || gfc_is_class_array_ref (e, NULL)); unlimited = UNLIMITED_POLY (e); for (ref = e->ref; ref; ref = ref->next) if (ref->type == REF_ARRAY && ref->u.ar.type == AR_FULL && ref->next) { whole_array = false; break; } /* Assignments to the string length need to be generated, when ( sym is a char array or sym has a _len component) and the associated expression is unlimited polymorphic, which is not (yet) correctly in 'unlimited', because for an already associated BT_DERIVED the u-poly flag is not set, i.e., __tmp_CHARACTER_0_1 => w => arg ^ generated temp ^ from code, the w does not have the u-poly flag set, where UNLIMITED_POLY(e) expects it. */ need_len_assign = ((unlimited || (e->ts.type == BT_DERIVED && e->ts.u.derived->attr.unlimited_polymorphic)) && (sym->ts.type == BT_CHARACTER || ((sym->ts.type == BT_CLASS || sym->ts.type == BT_DERIVED) && class_has_len_component (sym))) && !sym->attr.select_rank_temporary); /* Do a `pointer assignment' with updated descriptor (or assign descriptor to array temporary) for arrays with either unknown shape or if associating to a variable. Select rank temporaries need somewhat different treatment to other associate names and case temporaries. This because the selector is assumed rank and so the offset in particular has to be changed. Also, the case temporaries carry both allocatable and target attributes if present in the selector. This means that an allocatation or change of association can occur and so has to be dealt with. */ if (sym->attr.select_rank_temporary) { gfc_se se; tree class_decl = NULL_TREE; int rank = 0; bool class_ptr; sym2 = e->symtree->n.sym; gfc_init_se (&se, NULL); if (e->ts.type == BT_CLASS) { /* Go straight to the class data. */ if (sym2->attr.dummy) { class_decl = DECL_LANG_SPECIFIC (sym2->backend_decl) ? GFC_DECL_SAVED_DESCRIPTOR (sym2->backend_decl) : sym2->backend_decl; if (POINTER_TYPE_P (TREE_TYPE (class_decl))) class_decl = build_fold_indirect_ref_loc (input_location, class_decl); gcc_assert (GFC_CLASS_TYPE_P (TREE_TYPE (class_decl))); se.expr = gfc_class_data_get (class_decl); } else { class_decl = sym2->backend_decl; gfc_conv_expr_descriptor (&se, e); if (POINTER_TYPE_P (TREE_TYPE (se.expr))) se.expr = build_fold_indirect_ref_loc (input_location, se.expr); } if (CLASS_DATA (sym)->as && CLASS_DATA (sym)->as->rank > 0) rank = CLASS_DATA (sym)->as->rank; } else { gfc_conv_expr_descriptor (&se, e); if (sym->as && sym->as->rank > 0) rank = sym->as->rank; } desc = sym->backend_decl; /* The SELECT TYPE mechanisms turn class temporaries into pointers, which point to the selector. */ class_ptr = class_decl != NULL_TREE && POINTER_TYPE_P (TREE_TYPE (desc)); if (class_ptr) { tmp = gfc_create_var (TREE_TYPE (TREE_TYPE (desc)), "class"); tmp = gfc_build_addr_expr (NULL, tmp); gfc_add_modify (&se.pre, desc, tmp); tmp = gfc_class_vptr_get (class_decl); gfc_add_modify (&se.pre, gfc_class_vptr_get (desc), tmp); if (UNLIMITED_POLY (sym)) gfc_add_modify (&se.pre, gfc_class_len_get (desc), gfc_class_len_get (class_decl)); desc = gfc_class_data_get (desc); } /* SELECT RANK temporaries can carry the allocatable and pointer attributes so the selector descriptor must be copied in and copied out. */ if (rank > 0) copy_descriptor (&se.pre, desc, se.expr, rank); else { tmp = gfc_conv_descriptor_data_get (se.expr); gfc_add_modify (&se.pre, desc, fold_convert (TREE_TYPE (desc), tmp)); } /* Deal with associate_name => selector. Class associate names are treated in the same way as in SELECT TYPE. */ sym2 = sym->assoc->target->symtree->n.sym; if (sym2->assoc && sym->assoc->target && sym2->ts.type != BT_CLASS) { sym2 = sym2->assoc->target->symtree->n.sym; se.expr = sym2->backend_decl; if (POINTER_TYPE_P (TREE_TYPE (se.expr))) se.expr = build_fold_indirect_ref_loc (input_location, se.expr); } /* There could have been reallocation. Copy descriptor back to the selector and update the offset. */ if (sym->attr.allocatable || sym->attr.pointer || (sym->ts.type == BT_CLASS && (CLASS_DATA (sym)->attr.allocatable || CLASS_DATA (sym)->attr.pointer))) { if (rank > 0) copy_descriptor (&se.post, se.expr, desc, rank); else gfc_conv_descriptor_data_set (&se.post, se.expr, desc); /* The dynamic type could have changed too. */ if (sym->ts.type == BT_CLASS) { tmp = sym->backend_decl; if (class_ptr) tmp = build_fold_indirect_ref_loc (input_location, tmp); gfc_add_modify (&se.post, gfc_class_vptr_get (class_decl), gfc_class_vptr_get (tmp)); if (UNLIMITED_POLY (sym)) gfc_add_modify (&se.post, gfc_class_len_get (class_decl), gfc_class_len_get (tmp)); } } tmp = gfc_finish_block (&se.post); gfc_add_init_cleanup (block, gfc_finish_block (&se.pre), tmp); } /* Now all the other kinds of associate variable. */ else if (sym->attr.dimension && !class_target && (sym->as->type == AS_DEFERRED || sym->assoc->variable)) { gfc_se se; tree desc; bool cst_array_ctor; desc = sym->backend_decl; cst_array_ctor = e->expr_type == EXPR_ARRAY && gfc_constant_array_constructor_p (e->value.constructor) && e->ts.type != BT_CHARACTER; /* If association is to an expression, evaluate it and create temporary. Otherwise, get descriptor of target for pointer assignment. */ gfc_init_se (&se, NULL); if (sym->assoc->variable || cst_array_ctor) { se.direct_byref = 1; se.use_offset = 1; se.expr = desc; GFC_DECL_PTR_ARRAY_P (sym->backend_decl) = 1; } gfc_conv_expr_descriptor (&se, e); if (sym->ts.type == BT_CHARACTER && !se.direct_byref && sym->ts.deferred && !sym->attr.select_type_temporary && VAR_P (sym->ts.u.cl->backend_decl) && se.string_length != sym->ts.u.cl->backend_decl) { gfc_add_modify (&se.pre, sym->ts.u.cl->backend_decl, fold_convert (TREE_TYPE (sym->ts.u.cl->backend_decl), se.string_length)); } /* If we didn't already do the pointer assignment, set associate-name descriptor to the one generated for the temporary. */ if ((!sym->assoc->variable && !cst_array_ctor) || !whole_array) { int dim; if (whole_array) gfc_add_modify (&se.pre, desc, se.expr); /* The generated descriptor has lower bound zero (as array temporary), shift bounds so we get lower bounds of 1. */ for (dim = 0; dim < e->rank; ++dim) gfc_conv_shift_descriptor_lbound (&se.pre, desc, dim, gfc_index_one_node); } /* If this is a subreference array pointer associate name use the associate variable element size for the value of 'span'. */ if (sym->attr.subref_array_pointer && !se.direct_byref) { gcc_assert (e->expr_type == EXPR_VARIABLE); tmp = gfc_get_array_span (se.expr, e); gfc_conv_descriptor_span_set (&se.pre, desc, tmp); } if (e->expr_type == EXPR_FUNCTION && sym->ts.type == BT_DERIVED && sym->ts.u.derived && sym->ts.u.derived->attr.pdt_type) { tmp = gfc_deallocate_pdt_comp (sym->ts.u.derived, se.expr, sym->as->rank); gfc_add_expr_to_block (&se.post, tmp); } /* Done, register stuff as init / cleanup code. */ gfc_add_init_cleanup (block, gfc_finish_block (&se.pre), gfc_finish_block (&se.post)); } /* Temporaries, arising from TYPE IS, just need the descriptor of class arrays to be assigned directly. */ else if (class_target && sym->attr.dimension && (sym->ts.type == BT_DERIVED || unlimited)) { gfc_se se; gfc_init_se (&se, NULL); se.descriptor_only = 1; /* In a select type the (temporary) associate variable shall point to a standard fortran array (lower bound == 1), but conv_expr () just maps to the input array in the class object, whose lbound may be arbitrary. conv_expr_descriptor solves this by inserting a temporary array descriptor. */ gfc_conv_expr_descriptor (&se, e); gcc_assert (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (se.expr)) || GFC_ARRAY_TYPE_P (TREE_TYPE (se.expr))); gcc_assert (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (sym->backend_decl))); if (GFC_ARRAY_TYPE_P (TREE_TYPE (se.expr))) { if (INDIRECT_REF_P (se.expr)) tmp = TREE_OPERAND (se.expr, 0); else tmp = se.expr; gfc_add_modify (&se.pre, sym->backend_decl, gfc_class_data_get (GFC_DECL_SAVED_DESCRIPTOR (tmp))); } else gfc_add_modify (&se.pre, sym->backend_decl, se.expr); if (unlimited) { /* Recover the dtype, which has been overwritten by the assignment from an unlimited polymorphic object. */ tmp = gfc_conv_descriptor_dtype (sym->backend_decl); gfc_add_modify (&se.pre, tmp, gfc_get_dtype (TREE_TYPE (sym->backend_decl))); } gfc_add_init_cleanup (block, gfc_finish_block (&se.pre), gfc_finish_block (&se.post)); } /* Do a scalar pointer assignment; this is for scalar variable targets. */ else if (gfc_is_associate_pointer (sym)) { gfc_se se; gcc_assert (!sym->attr.dimension); gfc_init_se (&se, NULL); /* Class associate-names come this way because they are unconditionally associate pointers and the symbol is scalar. */ if (sym->ts.type == BT_CLASS && CLASS_DATA (sym)->attr.dimension) { tree target_expr; /* For a class array we need a descriptor for the selector. */ gfc_conv_expr_descriptor (&se, e); /* Needed to get/set the _len component below. */ target_expr = se.expr; /* Obtain a temporary class container for the result. */ gfc_conv_class_to_class (&se, e, sym->ts, false, true, false, false); se.expr = build_fold_indirect_ref_loc (input_location, se.expr); /* Set the offset. */ desc = gfc_class_data_get (se.expr); offset = gfc_index_zero_node; for (n = 0; n < e->rank; n++) { dim = gfc_rank_cst[n]; tmp = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, gfc_conv_descriptor_stride_get (desc, dim), gfc_conv_descriptor_lbound_get (desc, dim)); offset = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, offset, tmp); } if (need_len_assign) { if (e->symtree && DECL_LANG_SPECIFIC (e->symtree->n.sym->backend_decl) && GFC_DECL_SAVED_DESCRIPTOR (e->symtree->n.sym->backend_decl) && TREE_CODE (target_expr) != COMPONENT_REF) /* Use the original class descriptor stored in the saved descriptor to get the target_expr. */ target_expr = GFC_DECL_SAVED_DESCRIPTOR (e->symtree->n.sym->backend_decl); else /* Strip the _data component from the target_expr. */ target_expr = TREE_OPERAND (target_expr, 0); /* Add a reference to the _len comp to the target expr. */ tmp = gfc_class_len_get (target_expr); /* Get the component-ref for the temp structure's _len comp. */ charlen = gfc_class_len_get (se.expr); /* Add the assign to the beginning of the block... */ gfc_add_modify (&se.pre, charlen, fold_convert (TREE_TYPE (charlen), tmp)); /* and the oposite way at the end of the block, to hand changes on the string length back. */ gfc_add_modify (&se.post, tmp, fold_convert (TREE_TYPE (tmp), charlen)); /* Length assignment done, prevent adding it again below. */ need_len_assign = false; } gfc_conv_descriptor_offset_set (&se.pre, desc, offset); } else if (sym->ts.type == BT_CLASS && e->ts.type == BT_CLASS && CLASS_DATA (e)->attr.dimension) { /* This is bound to be a class array element. */ gfc_conv_expr_reference (&se, e); /* Get the _vptr component of the class object. */ tmp = gfc_get_vptr_from_expr (se.expr); /* Obtain a temporary class container for the result. */ gfc_conv_derived_to_class (&se, e, sym->ts, tmp, false, false); se.expr = build_fold_indirect_ref_loc (input_location, se.expr); } else { /* For BT_CLASS and BT_DERIVED, this boils down to a pointer assign, which has the string length included. For CHARACTERS it is still needed and will be done at the end of this routine. */ gfc_conv_expr (&se, e); need_len_assign = need_len_assign && sym->ts.type == BT_CHARACTER; } if (sym->ts.type == BT_CHARACTER && !sym->attr.select_type_temporary && VAR_P (sym->ts.u.cl->backend_decl) && se.string_length != sym->ts.u.cl->backend_decl) { gfc_add_modify (&se.pre, sym->ts.u.cl->backend_decl, fold_convert (TREE_TYPE (sym->ts.u.cl->backend_decl), se.string_length)); if (e->expr_type == EXPR_FUNCTION) { tmp = gfc_call_free (sym->backend_decl); gfc_add_expr_to_block (&se.post, tmp); } } if (sym->ts.type == BT_CHARACTER && e->ts.type == BT_CHARACTER && POINTER_TYPE_P (TREE_TYPE (se.expr))) { /* These are pointer types already. */ tmp = fold_convert (TREE_TYPE (sym->backend_decl), se.expr); } else { tree ctree = gfc_get_class_from_expr (se.expr); tmp = TREE_TYPE (sym->backend_decl); /* Coarray scalar component expressions can emerge from the front end as array elements of the _data field. */ if (sym->ts.type == BT_CLASS && e->ts.type == BT_CLASS && e->rank == 0 && !GFC_CLASS_TYPE_P (TREE_TYPE (se.expr)) && ctree) { tree stmp; tree dtmp; se.expr = ctree; dtmp = TREE_TYPE (TREE_TYPE (sym->backend_decl)); ctree = gfc_create_var (dtmp, "class"); stmp = gfc_class_data_get (se.expr); gcc_assert (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (stmp))); /* Set the fields of the target class variable. */ stmp = gfc_conv_descriptor_data_get (stmp); dtmp = gfc_class_data_get (ctree); stmp = fold_convert (TREE_TYPE (dtmp), stmp); gfc_add_modify (&se.pre, dtmp, stmp); stmp = gfc_class_vptr_get (se.expr); dtmp = gfc_class_vptr_get (ctree); stmp = fold_convert (TREE_TYPE (dtmp), stmp); gfc_add_modify (&se.pre, dtmp, stmp); if (UNLIMITED_POLY (sym)) { stmp = gfc_class_len_get (se.expr); dtmp = gfc_class_len_get (ctree); stmp = fold_convert (TREE_TYPE (dtmp), stmp); gfc_add_modify (&se.pre, dtmp, stmp); } se.expr = ctree; } tmp = gfc_build_addr_expr (tmp, se.expr); } gfc_add_modify (&se.pre, sym->backend_decl, tmp); gfc_add_init_cleanup (block, gfc_finish_block( &se.pre), gfc_finish_block (&se.post)); } /* Do a simple assignment. This is for scalar expressions, where we can simply use expression assignment. */ else { gfc_expr *lhs; tree res; gfc_se se; gfc_init_se (&se, NULL); /* resolve.c converts some associate names to allocatable so that allocation can take place automatically in gfc_trans_assignment. The frontend prevents them from being either allocated, deallocated or reallocated. */ if (sym->attr.allocatable) { tmp = sym->backend_decl; if (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (tmp))) tmp = gfc_conv_descriptor_data_get (tmp); gfc_add_modify (&se.pre, tmp, fold_convert (TREE_TYPE (tmp), null_pointer_node)); } lhs = gfc_lval_expr_from_sym (sym); res = gfc_trans_assignment (lhs, e, false, true); gfc_add_expr_to_block (&se.pre, res); tmp = sym->backend_decl; if (e->expr_type == EXPR_FUNCTION && sym->ts.type == BT_DERIVED && sym->ts.u.derived && sym->ts.u.derived->attr.pdt_type) { tmp = gfc_deallocate_pdt_comp (sym->ts.u.derived, tmp, 0); } else if (e->expr_type == EXPR_FUNCTION && sym->ts.type == BT_CLASS && CLASS_DATA (sym)->ts.u.derived && CLASS_DATA (sym)->ts.u.derived->attr.pdt_type) { tmp = gfc_class_data_get (tmp); tmp = gfc_deallocate_pdt_comp (CLASS_DATA (sym)->ts.u.derived, tmp, 0); } else if (sym->attr.allocatable) { tmp = sym->backend_decl; if (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (tmp))) tmp = gfc_conv_descriptor_data_get (tmp); /* A simple call to free suffices here. */ tmp = gfc_call_free (tmp); /* Make sure that reallocation on assignment cannot occur. */ sym->attr.allocatable = 0; } else tmp = NULL_TREE; res = gfc_finish_block (&se.pre); gfc_add_init_cleanup (block, res, tmp); gfc_free_expr (lhs); } /* Set the stringlength, when needed. */ if (need_len_assign) { gfc_se se; gfc_init_se (&se, NULL); if (e->symtree->n.sym->ts.type == BT_CHARACTER) { /* Deferred strings are dealt with in the preceeding. */ gcc_assert (!e->symtree->n.sym->ts.deferred); tmp = e->symtree->n.sym->ts.u.cl->backend_decl; } else if (e->symtree->n.sym->attr.function && e->symtree->n.sym == e->symtree->n.sym->result) { tmp = gfc_get_fake_result_decl (e->symtree->n.sym, 0); tmp = gfc_class_len_get (tmp); } else tmp = gfc_class_len_get (gfc_get_symbol_decl (e->symtree->n.sym)); gfc_get_symbol_decl (sym); charlen = sym->ts.type == BT_CHARACTER ? sym->ts.u.cl->backend_decl : gfc_class_len_get (sym->backend_decl); /* Prevent adding a noop len= len. */ if (tmp != charlen) { gfc_add_modify (&se.pre, charlen, fold_convert (TREE_TYPE (charlen), tmp)); gfc_add_init_cleanup (block, gfc_finish_block (&se.pre), gfc_finish_block (&se.post)); } } } /* Translate a BLOCK construct. This is basically what we would do for a procedure body. */ tree gfc_trans_block_construct (gfc_code* code) { gfc_namespace* ns; gfc_symbol* sym; gfc_wrapped_block block; tree exit_label; stmtblock_t body; gfc_association_list *ass; ns = code->ext.block.ns; gcc_assert (ns); sym = ns->proc_name; gcc_assert (sym); /* Process local variables. */ gcc_assert (!sym->tlink); sym->tlink = sym; gfc_process_block_locals (ns); /* Generate code including exit-label. */ gfc_init_block (&body); exit_label = gfc_build_label_decl (NULL_TREE); code->exit_label = exit_label; finish_oacc_declare (ns, sym, true); gfc_add_expr_to_block (&body, gfc_trans_code (ns->code)); gfc_add_expr_to_block (&body, build1_v (LABEL_EXPR, exit_label)); /* Finish everything. */ gfc_start_wrapped_block (&block, gfc_finish_block (&body)); gfc_trans_deferred_vars (sym, &block); for (ass = code->ext.block.assoc; ass; ass = ass->next) trans_associate_var (ass->st->n.sym, &block); return gfc_finish_wrapped_block (&block); } /* Translate the simple DO construct in a C-style manner. This is where the loop variable has integer type and step +-1. Following code will generate infinite loop in case where TO is INT_MAX (for +1 step) or INT_MIN (for -1 step) We translate a do loop from: DO dovar = from, to, step body END DO to: [Evaluate loop bounds and step] dovar = from; for (;;) { if (dovar > to) goto end_label; body; cycle_label: dovar += step; } end_label: This helps the optimizers by avoiding the extra pre-header condition and we save a register as we just compare the updated IV (not a value in previous step). */ static tree gfc_trans_simple_do (gfc_code * code, stmtblock_t *pblock, tree dovar, tree from, tree to, tree step, tree exit_cond) { stmtblock_t body; tree type; tree cond; tree tmp; tree saved_dovar = NULL; tree cycle_label; tree exit_label; location_t loc; type = TREE_TYPE (dovar); bool is_step_positive = tree_int_cst_sgn (step) > 0; loc = gfc_get_location (&code->ext.iterator->start->where); /* Initialize the DO variable: dovar = from. */ gfc_add_modify_loc (loc, pblock, dovar, fold_convert (TREE_TYPE (dovar), from)); /* Save value for do-tinkering checking. */ if (gfc_option.rtcheck & GFC_RTCHECK_DO) { saved_dovar = gfc_create_var (type, ".saved_dovar"); gfc_add_modify_loc (loc, pblock, saved_dovar, dovar); } /* Cycle and exit statements are implemented with gotos. */ cycle_label = gfc_build_label_decl (NULL_TREE); exit_label = gfc_build_label_decl (NULL_TREE); /* Put the labels where they can be found later. See gfc_trans_do(). */ code->cycle_label = cycle_label; code->exit_label = exit_label; /* Loop body. */ gfc_start_block (&body); /* Exit the loop if there is an I/O result condition or error. */ if (exit_cond) { tmp = build1_v (GOTO_EXPR, exit_label); tmp = fold_build3_loc (loc, COND_EXPR, void_type_node, exit_cond, tmp, build_empty_stmt (loc)); gfc_add_expr_to_block (&body, tmp); } /* Evaluate the loop condition. */ if (is_step_positive) cond = fold_build2_loc (loc, GT_EXPR, logical_type_node, dovar, fold_convert (type, to)); else cond = fold_build2_loc (loc, LT_EXPR, logical_type_node, dovar, fold_convert (type, to)); cond = gfc_evaluate_now_loc (loc, cond, &body); if (code->ext.iterator->unroll && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_unroll_kind), build_int_cst (integer_type_node, code->ext.iterator->unroll)); if (code->ext.iterator->ivdep && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_ivdep_kind), integer_zero_node); if (code->ext.iterator->vector && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_vector_kind), integer_zero_node); if (code->ext.iterator->novector && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_no_vector_kind), integer_zero_node); /* The loop exit. */ tmp = fold_build1_loc (loc, GOTO_EXPR, void_type_node, exit_label); TREE_USED (exit_label) = 1; tmp = fold_build3_loc (loc, COND_EXPR, void_type_node, cond, tmp, build_empty_stmt (loc)); gfc_add_expr_to_block (&body, tmp); /* Check whether the induction variable is equal to INT_MAX (respectively to INT_MIN). */ if (gfc_option.rtcheck & GFC_RTCHECK_DO) { tree boundary = is_step_positive ? TYPE_MAX_VALUE (type) : TYPE_MIN_VALUE (type); tmp = fold_build2_loc (loc, EQ_EXPR, logical_type_node, dovar, boundary); gfc_trans_runtime_check (true, false, tmp, &body, &code->loc, "Loop iterates infinitely"); } /* Main loop body. */ tmp = gfc_trans_code_cond (code->block->next, exit_cond); gfc_add_expr_to_block (&body, tmp); /* Label for cycle statements (if needed). */ if (TREE_USED (cycle_label)) { tmp = build1_v (LABEL_EXPR, cycle_label); gfc_add_expr_to_block (&body, tmp); } /* Check whether someone has modified the loop variable. */ if (gfc_option.rtcheck & GFC_RTCHECK_DO) { tmp = fold_build2_loc (loc, NE_EXPR, logical_type_node, dovar, saved_dovar); gfc_trans_runtime_check (true, false, tmp, &body, &code->loc, "Loop variable has been modified"); } /* Increment the loop variable. */ tmp = fold_build2_loc (loc, PLUS_EXPR, type, dovar, step); gfc_add_modify_loc (loc, &body, dovar, tmp); if (gfc_option.rtcheck & GFC_RTCHECK_DO) gfc_add_modify_loc (loc, &body, saved_dovar, dovar); /* Finish the loop body. */ tmp = gfc_finish_block (&body); tmp = fold_build1_loc (loc, LOOP_EXPR, void_type_node, tmp); gfc_add_expr_to_block (pblock, tmp); /* Add the exit label. */ tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (pblock, tmp); return gfc_finish_block (pblock); } /* Translate the DO construct. This obviously is one of the most important ones to get right with any compiler, but especially so for Fortran. We special case some loop forms as described in gfc_trans_simple_do. For other cases we implement them with a separate loop count, as described in the standard. We translate a do loop from: DO dovar = from, to, step body END DO to: [evaluate loop bounds and step] empty = (step > 0 ? to < from : to > from); countm1 = (to - from) / step; dovar = from; if (empty) goto exit_label; for (;;) { body; cycle_label: dovar += step countm1t = countm1; countm1--; if (countm1t == 0) goto exit_label; } exit_label: countm1 is an unsigned integer. It is equal to the loop count minus one, because the loop count itself can overflow. */ tree gfc_trans_do (gfc_code * code, tree exit_cond) { gfc_se se; tree dovar; tree saved_dovar = NULL; tree from; tree to; tree step; tree countm1; tree type; tree utype; tree cond; tree cycle_label; tree exit_label; tree tmp; stmtblock_t block; stmtblock_t body; location_t loc; gfc_start_block (&block); loc = gfc_get_location (&code->ext.iterator->start->where); /* Evaluate all the expressions in the iterator. */ gfc_init_se (&se, NULL); gfc_conv_expr_lhs (&se, code->ext.iterator->var); gfc_add_block_to_block (&block, &se.pre); dovar = se.expr; type = TREE_TYPE (dovar); gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, code->ext.iterator->start); gfc_add_block_to_block (&block, &se.pre); from = gfc_evaluate_now (se.expr, &block); gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, code->ext.iterator->end); gfc_add_block_to_block (&block, &se.pre); to = gfc_evaluate_now (se.expr, &block); gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, code->ext.iterator->step); gfc_add_block_to_block (&block, &se.pre); step = gfc_evaluate_now (se.expr, &block); if (gfc_option.rtcheck & GFC_RTCHECK_DO) { tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, step, build_zero_cst (type)); gfc_trans_runtime_check (true, false, tmp, &block, &code->loc, "DO step value is zero"); } /* Special case simple loops. */ if (TREE_CODE (type) == INTEGER_TYPE && (integer_onep (step) || tree_int_cst_equal (step, integer_minus_one_node))) return gfc_trans_simple_do (code, &block, dovar, from, to, step, exit_cond); if (TREE_CODE (type) == INTEGER_TYPE) utype = unsigned_type_for (type); else utype = unsigned_type_for (gfc_array_index_type); countm1 = gfc_create_var (utype, "countm1"); /* Cycle and exit statements are implemented with gotos. */ cycle_label = gfc_build_label_decl (NULL_TREE); exit_label = gfc_build_label_decl (NULL_TREE); TREE_USED (exit_label) = 1; /* Put these labels where they can be found later. */ code->cycle_label = cycle_label; code->exit_label = exit_label; /* Initialize the DO variable: dovar = from. */ gfc_add_modify (&block, dovar, from); /* Save value for do-tinkering checking. */ if (gfc_option.rtcheck & GFC_RTCHECK_DO) { saved_dovar = gfc_create_var (type, ".saved_dovar"); gfc_add_modify_loc (loc, &block, saved_dovar, dovar); } /* Initialize loop count and jump to exit label if the loop is empty. This code is executed before we enter the loop body. We generate: if (step > 0) { countm1 = (to - from) / step; if (to < from) goto exit_label; } else { countm1 = (from - to) / -step; if (to > from) goto exit_label; } */ if (TREE_CODE (type) == INTEGER_TYPE) { tree pos, neg, tou, fromu, stepu, tmp2; /* The distance from FROM to TO cannot always be represented in a signed type, thus use unsigned arithmetic, also to avoid any undefined overflow issues. */ tou = fold_convert (utype, to); fromu = fold_convert (utype, from); stepu = fold_convert (utype, step); /* For a positive step, when to < from, exit, otherwise compute countm1 = ((unsigned)to - (unsigned)from) / (unsigned)step */ tmp = fold_build2_loc (loc, LT_EXPR, logical_type_node, to, from); tmp2 = fold_build2_loc (loc, TRUNC_DIV_EXPR, utype, fold_build2_loc (loc, MINUS_EXPR, utype, tou, fromu), stepu); pos = build2 (COMPOUND_EXPR, void_type_node, fold_build2 (MODIFY_EXPR, void_type_node, countm1, tmp2), build3_loc (loc, COND_EXPR, void_type_node, gfc_unlikely (tmp, PRED_FORTRAN_LOOP_PREHEADER), build1_loc (loc, GOTO_EXPR, void_type_node, exit_label), NULL_TREE)); /* For a negative step, when to > from, exit, otherwise compute countm1 = ((unsigned)from - (unsigned)to) / -(unsigned)step */ tmp = fold_build2_loc (loc, GT_EXPR, logical_type_node, to, from); tmp2 = fold_build2_loc (loc, TRUNC_DIV_EXPR, utype, fold_build2_loc (loc, MINUS_EXPR, utype, fromu, tou), fold_build1_loc (loc, NEGATE_EXPR, utype, stepu)); neg = build2 (COMPOUND_EXPR, void_type_node, fold_build2 (MODIFY_EXPR, void_type_node, countm1, tmp2), build3_loc (loc, COND_EXPR, void_type_node, gfc_unlikely (tmp, PRED_FORTRAN_LOOP_PREHEADER), build1_loc (loc, GOTO_EXPR, void_type_node, exit_label), NULL_TREE)); tmp = fold_build2_loc (loc, LT_EXPR, logical_type_node, step, build_int_cst (TREE_TYPE (step), 0)); tmp = fold_build3_loc (loc, COND_EXPR, void_type_node, tmp, neg, pos); gfc_add_expr_to_block (&block, tmp); } else { tree pos_step; /* TODO: We could use the same width as the real type. This would probably cause more problems that it solves when we implement "long double" types. */ tmp = fold_build2_loc (loc, MINUS_EXPR, type, to, from); tmp = fold_build2_loc (loc, RDIV_EXPR, type, tmp, step); tmp = fold_build1_loc (loc, FIX_TRUNC_EXPR, utype, tmp); gfc_add_modify (&block, countm1, tmp); /* We need a special check for empty loops: empty = (step > 0 ? to < from : to > from); */ pos_step = fold_build2_loc (loc, GT_EXPR, logical_type_node, step, build_zero_cst (type)); tmp = fold_build3_loc (loc, COND_EXPR, logical_type_node, pos_step, fold_build2_loc (loc, LT_EXPR, logical_type_node, to, from), fold_build2_loc (loc, GT_EXPR, logical_type_node, to, from)); /* If the loop is empty, go directly to the exit label. */ tmp = fold_build3_loc (loc, COND_EXPR, void_type_node, tmp, build1_v (GOTO_EXPR, exit_label), build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } /* Loop body. */ gfc_start_block (&body); /* Main loop body. */ tmp = gfc_trans_code_cond (code->block->next, exit_cond); gfc_add_expr_to_block (&body, tmp); /* Label for cycle statements (if needed). */ if (TREE_USED (cycle_label)) { tmp = build1_v (LABEL_EXPR, cycle_label); gfc_add_expr_to_block (&body, tmp); } /* Check whether someone has modified the loop variable. */ if (gfc_option.rtcheck & GFC_RTCHECK_DO) { tmp = fold_build2_loc (loc, NE_EXPR, logical_type_node, dovar, saved_dovar); gfc_trans_runtime_check (true, false, tmp, &body, &code->loc, "Loop variable has been modified"); } /* Exit the loop if there is an I/O result condition or error. */ if (exit_cond) { tmp = build1_v (GOTO_EXPR, exit_label); tmp = fold_build3_loc (loc, COND_EXPR, void_type_node, exit_cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&body, tmp); } /* Increment the loop variable. */ tmp = fold_build2_loc (loc, PLUS_EXPR, type, dovar, step); gfc_add_modify_loc (loc, &body, dovar, tmp); if (gfc_option.rtcheck & GFC_RTCHECK_DO) gfc_add_modify_loc (loc, &body, saved_dovar, dovar); /* Initialize countm1t. */ tree countm1t = gfc_create_var (utype, "countm1t"); gfc_add_modify_loc (loc, &body, countm1t, countm1); /* Decrement the loop count. */ tmp = fold_build2_loc (loc, MINUS_EXPR, utype, countm1, build_int_cst (utype, 1)); gfc_add_modify_loc (loc, &body, countm1, tmp); /* End with the loop condition. Loop until countm1t == 0. */ cond = fold_build2_loc (loc, EQ_EXPR, logical_type_node, countm1t, build_int_cst (utype, 0)); if (code->ext.iterator->unroll && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_unroll_kind), build_int_cst (integer_type_node, code->ext.iterator->unroll)); if (code->ext.iterator->ivdep && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_ivdep_kind), integer_zero_node); if (code->ext.iterator->vector && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_vector_kind), integer_zero_node); if (code->ext.iterator->novector && cond != error_mark_node) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_no_vector_kind), integer_zero_node); tmp = fold_build1_loc (loc, GOTO_EXPR, void_type_node, exit_label); tmp = fold_build3_loc (loc, COND_EXPR, void_type_node, cond, tmp, build_empty_stmt (loc)); gfc_add_expr_to_block (&body, tmp); /* End of loop body. */ tmp = gfc_finish_block (&body); /* The for loop itself. */ tmp = fold_build1_loc (loc, LOOP_EXPR, void_type_node, tmp); 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); return gfc_finish_block (&block); } /* Translate the DO WHILE construct. We translate DO WHILE (cond) body END DO to: for ( ; ; ) { pre_cond; if (! cond) goto exit_label; body; cycle_label: } exit_label: Because the evaluation of the exit condition `cond' may have side effects, we can't do much for empty loop bodies. The backend optimizers should be smart enough to eliminate any dead loops. */ tree gfc_trans_do_while (gfc_code * code) { gfc_se cond; tree tmp; tree cycle_label; tree exit_label; stmtblock_t block; /* Everything we build here is part of the loop body. */ gfc_start_block (&block); /* Cycle and exit statements are implemented with gotos. */ cycle_label = gfc_build_label_decl (NULL_TREE); exit_label = gfc_build_label_decl (NULL_TREE); /* Put the labels where they can be found later. See gfc_trans_do(). */ code->cycle_label = cycle_label; code->exit_label = exit_label; /* Create a GIMPLE version of the exit condition. */ gfc_init_se (&cond, NULL); gfc_conv_expr_val (&cond, code->expr1); gfc_add_block_to_block (&block, &cond.pre); cond.expr = fold_build1_loc (gfc_get_location (&code->expr1->where), TRUTH_NOT_EXPR, TREE_TYPE (cond.expr), cond.expr); /* Build "IF (! cond) GOTO exit_label". */ tmp = build1_v (GOTO_EXPR, exit_label); TREE_USED (exit_label) = 1; tmp = fold_build3_loc (gfc_get_location (&code->expr1->where), COND_EXPR, void_type_node, cond.expr, tmp, build_empty_stmt (gfc_get_location ( &code->expr1->where))); gfc_add_expr_to_block (&block, tmp); /* The main body of the loop. */ tmp = gfc_trans_code (code->block->next); gfc_add_expr_to_block (&block, tmp); /* Label for cycle statements (if needed). */ if (TREE_USED (cycle_label)) { tmp = build1_v (LABEL_EXPR, cycle_label); gfc_add_expr_to_block (&block, tmp); } /* End of loop body. */ tmp = gfc_finish_block (&block); gfc_init_block (&block); /* Build the loop. */ tmp = fold_build1_loc (gfc_get_location (&code->expr1->where), LOOP_EXPR, void_type_node, tmp); 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); return gfc_finish_block (&block); } /* Deal with the particular case of SELECT_TYPE, where the vtable addresses are used for the selection. Since these are not sorted, the selection has to be made by a series of if statements. */ static tree gfc_trans_select_type_cases (gfc_code * code) { gfc_code *c; gfc_case *cp; tree tmp; tree cond; tree low; tree high; gfc_se se; gfc_se cse; stmtblock_t block; stmtblock_t body; bool def = false; gfc_expr *e; gfc_start_block (&block); /* Calculate the switch expression. */ gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, code->expr1); gfc_add_block_to_block (&block, &se.pre); /* Generate an expression for the selector hash value, for use to resolve character cases. */ e = gfc_copy_expr (code->expr1->value.function.actual->expr); gfc_add_hash_component (e); TREE_USED (code->exit_label) = 0; repeat: for (c = code->block; c; c = c->block) { cp = c->ext.block.case_list; /* Assume it's the default case. */ low = NULL_TREE; high = NULL_TREE; tmp = NULL_TREE; /* Put the default case at the end. */ if ((!def && !cp->low) || (def && cp->low)) continue; if (cp->low && (cp->ts.type == BT_CLASS || cp->ts.type == BT_DERIVED)) { gfc_init_se (&cse, NULL); gfc_conv_expr_val (&cse, cp->low); gfc_add_block_to_block (&block, &cse.pre); low = cse.expr; } else if (cp->ts.type != BT_UNKNOWN) { gcc_assert (cp->high); gfc_init_se (&cse, NULL); gfc_conv_expr_val (&cse, cp->high); gfc_add_block_to_block (&block, &cse.pre); high = cse.expr; } gfc_init_block (&body); /* Add the statements for this case. */ tmp = gfc_trans_code (c->next); gfc_add_expr_to_block (&body, tmp); /* Break to the end of the SELECT TYPE construct. The default case just falls through. */ if (!def) { TREE_USED (code->exit_label) = 1; tmp = build1_v (GOTO_EXPR, code->exit_label); gfc_add_expr_to_block (&body, tmp); } tmp = gfc_finish_block (&body); if (low != NULL_TREE) { /* Compare vtable pointers. */ cond = fold_build2_loc (input_location, EQ_EXPR, TREE_TYPE (se.expr), se.expr, low); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, cond, tmp, build_empty_stmt (input_location)); } else if (high != NULL_TREE) { /* Compare hash values for character cases. */ gfc_init_se (&cse, NULL); gfc_conv_expr_val (&cse, e); gfc_add_block_to_block (&block, &cse.pre); cond = fold_build2_loc (input_location, EQ_EXPR, TREE_TYPE (se.expr), high, cse.expr); 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); } if (!def) { def = true; goto repeat; } gfc_free_expr (e); return gfc_finish_block (&block); } /* Translate the SELECT CASE construct for INTEGER case expressions, without killing all potential optimizations. The problem is that Fortran allows unbounded cases, but the back-end does not, so we need to intercept those before we enter the equivalent SWITCH_EXPR we can build. For example, we translate this, SELECT CASE (expr) CASE (:100,101,105:115) block_1 CASE (190:199,200:) block_2 CASE (300) block_3 CASE DEFAULT block_4 END SELECT to the GENERIC equivalent, switch (expr) { case (minimum value for typeof(expr) ... 100: case 101: case 105 ... 114: block1: goto end_label; case 200 ... (maximum value for typeof(expr): case 190 ... 199: block2; goto end_label; case 300: block_3; goto end_label; default: block_4; goto end_label; } end_label: */ static tree gfc_trans_integer_select (gfc_code * code) { gfc_code *c; gfc_case *cp; tree end_label; tree tmp; gfc_se se; stmtblock_t block; stmtblock_t body; gfc_start_block (&block); /* Calculate the switch expression. */ gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, code->expr1); gfc_add_block_to_block (&block, &se.pre); end_label = gfc_build_label_decl (NULL_TREE); gfc_init_block (&body); for (c = code->block; c; c = c->block) { for (cp = c->ext.block.case_list; cp; cp = cp->next) { tree low, high; tree label; /* Assume it's the default case. */ low = high = NULL_TREE; if (cp->low) { low = gfc_conv_mpz_to_tree (cp->low->value.integer, cp->low->ts.kind); /* If there's only a lower bound, set the high bound to the maximum value of the case expression. */ if (!cp->high) high = TYPE_MAX_VALUE (TREE_TYPE (se.expr)); } if (cp->high) { /* Three cases are possible here: 1) There is no lower bound, e.g. CASE (:N). 2) There is a lower bound .NE. high bound, that is a case range, e.g. CASE (N:M) where M>N (we make sure that M>N during type resolution). 3) There is a lower bound, and it has the same value as the high bound, e.g. CASE (N:N). This is our internal representation of CASE(N). In the first and second case, we need to set a value for high. In the third case, we don't because the GCC middle end represents a single case value by just letting high be a NULL_TREE. We can't do that because we need to be able to represent unbounded cases. */ if (!cp->low || (mpz_cmp (cp->low->value.integer, cp->high->value.integer) != 0)) high = gfc_conv_mpz_to_tree (cp->high->value.integer, cp->high->ts.kind); /* Unbounded case. */ if (!cp->low) low = TYPE_MIN_VALUE (TREE_TYPE (se.expr)); } /* Build a label. */ label = gfc_build_label_decl (NULL_TREE); /* Add this case label. Add parameter 'label', make it match GCC backend. */ tmp = build_case_label (low, high, label); gfc_add_expr_to_block (&body, tmp); } /* Add the statements for this case. */ tmp = gfc_trans_code (c->next); gfc_add_expr_to_block (&body, tmp); /* Break to the end of the construct. */ tmp = build1_v (GOTO_EXPR, end_label); gfc_add_expr_to_block (&body, tmp); } tmp = gfc_finish_block (&body); tmp = fold_build2_loc (input_location, SWITCH_EXPR, NULL_TREE, se.expr, tmp); gfc_add_expr_to_block (&block, tmp); tmp = build1_v (LABEL_EXPR, end_label); gfc_add_expr_to_block (&block, tmp); return gfc_finish_block (&block); } /* Translate the SELECT CASE construct for LOGICAL case expressions. There are only two cases possible here, even though the standard does allow three cases in a LOGICAL SELECT CASE construct: .TRUE., .FALSE., and DEFAULT. We never generate more than two blocks here. Instead, we always try to eliminate the DEFAULT case. This way, we can translate this kind of SELECT construct to a simple if {} else {}; expression in GENERIC. */ static tree gfc_trans_logical_select (gfc_code * code) { gfc_code *c; gfc_code *t, *f, *d; gfc_case *cp; gfc_se se; stmtblock_t block; /* Assume we don't have any cases at all. */ t = f = d = NULL; /* Now see which ones we actually do have. We can have at most two cases in a single case list: one for .TRUE. and one for .FALSE. The default case is always separate. If the cases for .TRUE. and .FALSE. are in the same case list, the block for that case list always executed, and we don't generate code a COND_EXPR. */ for (c = code->block; c; c = c->block) { for (cp = c->ext.block.case_list; cp; cp = cp->next) { if (cp->low) { if (cp->low->value.logical == 0) /* .FALSE. */ f = c; else /* if (cp->value.logical != 0), thus .TRUE. */ t = c; } else d = c; } } /* Start a new block. */ gfc_start_block (&block); /* Calculate the switch expression. We always need to do this because it may have side effects. */ gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, code->expr1); gfc_add_block_to_block (&block, &se.pre); if (t == f && t != NULL) { /* Cases for .TRUE. and .FALSE. are in the same block. Just translate the code for these cases, append it to the current block. */ gfc_add_expr_to_block (&block, gfc_trans_code (t->next)); } else { tree true_tree, false_tree, stmt; true_tree = build_empty_stmt (input_location); false_tree = build_empty_stmt (input_location); /* If we have a case for .TRUE. and for .FALSE., discard the default case. Otherwise, if .TRUE. or .FALSE. is missing and there is a default case, make the missing case the default case. */ if (t != NULL && f != NULL) d = NULL; else if (d != NULL) { if (t == NULL) t = d; else f = d; } /* Translate the code for each of these blocks, and append it to the current block. */ if (t != NULL) true_tree = gfc_trans_code (t->next); if (f != NULL) false_tree = gfc_trans_code (f->next); stmt = fold_build3_loc (input_location, COND_EXPR, void_type_node, se.expr, true_tree, false_tree); gfc_add_expr_to_block (&block, stmt); } return gfc_finish_block (&block); } /* The jump table types are stored in static variables to avoid constructing them from scratch every single time. */ static GTY(()) tree select_struct[2]; /* Translate the SELECT CASE construct for CHARACTER case expressions. Instead of generating compares and jumps, it is far simpler to generate a data structure describing the cases in order and call a library subroutine that locates the right case. This is particularly true because this is the only case where we might have to dispose of a temporary. The library subroutine returns a pointer to jump to or NULL if no branches are to be taken. */ static tree gfc_trans_character_select (gfc_code *code) { tree init, end_label, tmp, type, case_num, label, fndecl; stmtblock_t block, body; gfc_case *cp, *d; gfc_code *c; gfc_se se, expr1se; int n, k; vec *inits = NULL; tree pchartype = gfc_get_pchar_type (code->expr1->ts.kind); /* The jump table types are stored in static variables to avoid constructing them from scratch every single time. */ static tree ss_string1[2], ss_string1_len[2]; static tree ss_string2[2], ss_string2_len[2]; static tree ss_target[2]; cp = code->block->ext.block.case_list; while (cp->left != NULL) cp = cp->left; /* Generate the body */ gfc_start_block (&block); gfc_init_se (&expr1se, NULL); gfc_conv_expr_reference (&expr1se, code->expr1); gfc_add_block_to_block (&block, &expr1se.pre); end_label = gfc_build_label_decl (NULL_TREE); gfc_init_block (&body); /* Attempt to optimize length 1 selects. */ if (integer_onep (expr1se.string_length)) { for (d = cp; d; d = d->right) { gfc_charlen_t i; if (d->low) { gcc_assert (d->low->expr_type == EXPR_CONSTANT && d->low->ts.type == BT_CHARACTER); if (d->low->value.character.length > 1) { for (i = 1; i < d->low->value.character.length; i++) if (d->low->value.character.string[i] != ' ') break; if (i != d->low->value.character.length) { if (optimize && d->high && i == 1) { gcc_assert (d->high->expr_type == EXPR_CONSTANT && d->high->ts.type == BT_CHARACTER); if (d->high->value.character.length > 1 && (d->low->value.character.string[0] == d->high->value.character.string[0]) && d->high->value.character.string[1] != ' ' && ((d->low->value.character.string[1] < ' ') == (d->high->value.character.string[1] < ' '))) continue; } break; } } } if (d->high) { gcc_assert (d->high->expr_type == EXPR_CONSTANT && d->high->ts.type == BT_CHARACTER); if (d->high->value.character.length > 1) { for (i = 1; i < d->high->value.character.length; i++) if (d->high->value.character.string[i] != ' ') break; if (i != d->high->value.character.length) break; } } } if (d == NULL) { tree ctype = gfc_get_char_type (code->expr1->ts.kind); for (c = code->block; c; c = c->block) { for (cp = c->ext.block.case_list; cp; cp = cp->next) { tree low, high; tree label; gfc_char_t r; /* Assume it's the default case. */ low = high = NULL_TREE; if (cp->low) { /* CASE ('ab') or CASE ('ab':'az') will never match any length 1 character. */ if (cp->low->value.character.length > 1 && cp->low->value.character.string[1] != ' ') continue; if (cp->low->value.character.length > 0) r = cp->low->value.character.string[0]; else r = ' '; low = build_int_cst (ctype, r); /* If there's only a lower bound, set the high bound to the maximum value of the case expression. */ if (!cp->high) high = TYPE_MAX_VALUE (ctype); } if (cp->high) { if (!cp->low || (cp->low->value.character.string[0] != cp->high->value.character.string[0])) { if (cp->high->value.character.length > 0) r = cp->high->value.character.string[0]; else r = ' '; high = build_int_cst (ctype, r); } /* Unbounded case. */ if (!cp->low) low = TYPE_MIN_VALUE (ctype); } /* Build a label. */ label = gfc_build_label_decl (NULL_TREE); /* Add this case label. Add parameter 'label', make it match GCC backend. */ tmp = build_case_label (low, high, label); gfc_add_expr_to_block (&body, tmp); } /* Add the statements for this case. */ tmp = gfc_trans_code (c->next); gfc_add_expr_to_block (&body, tmp); /* Break to the end of the construct. */ tmp = build1_v (GOTO_EXPR, end_label); gfc_add_expr_to_block (&body, tmp); } tmp = gfc_string_to_single_character (expr1se.string_length, expr1se.expr, code->expr1->ts.kind); case_num = gfc_create_var (ctype, "case_num"); gfc_add_modify (&block, case_num, tmp); gfc_add_block_to_block (&block, &expr1se.post); tmp = gfc_finish_block (&body); tmp = fold_build2_loc (input_location, SWITCH_EXPR, NULL_TREE, case_num, tmp); gfc_add_expr_to_block (&block, tmp); tmp = build1_v (LABEL_EXPR, end_label); gfc_add_expr_to_block (&block, tmp); return gfc_finish_block (&block); } } if (code->expr1->ts.kind == 1) k = 0; else if (code->expr1->ts.kind == 4) k = 1; else gcc_unreachable (); if (select_struct[k] == NULL) { tree *chain = NULL; select_struct[k] = make_node (RECORD_TYPE); if (code->expr1->ts.kind == 1) TYPE_NAME (select_struct[k]) = get_identifier ("_jump_struct_char1"); else if (code->expr1->ts.kind == 4) TYPE_NAME (select_struct[k]) = get_identifier ("_jump_struct_char4"); else gcc_unreachable (); #undef ADD_FIELD #define ADD_FIELD(NAME, TYPE) \ ss_##NAME[k] = gfc_add_field_to_struct (select_struct[k], \ get_identifier (stringize(NAME)), \ TYPE, \ &chain) ADD_FIELD (string1, pchartype); ADD_FIELD (string1_len, gfc_charlen_type_node); ADD_FIELD (string2, pchartype); ADD_FIELD (string2_len, gfc_charlen_type_node); ADD_FIELD (target, integer_type_node); #undef ADD_FIELD gfc_finish_type (select_struct[k]); } n = 0; for (d = cp; d; d = d->right) d->n = n++; for (c = code->block; c; c = c->block) { for (d = c->ext.block.case_list; d; d = d->next) { label = gfc_build_label_decl (NULL_TREE); tmp = build_case_label ((d->low == NULL && d->high == NULL) ? NULL : build_int_cst (integer_type_node, d->n), NULL, label); gfc_add_expr_to_block (&body, tmp); } tmp = gfc_trans_code (c->next); gfc_add_expr_to_block (&body, tmp); tmp = build1_v (GOTO_EXPR, end_label); gfc_add_expr_to_block (&body, tmp); } /* Generate the structure describing the branches */ for (d = cp; d; d = d->right) { vec *node = NULL; gfc_init_se (&se, NULL); if (d->low == NULL) { CONSTRUCTOR_APPEND_ELT (node, ss_string1[k], null_pointer_node); CONSTRUCTOR_APPEND_ELT (node, ss_string1_len[k], build_zero_cst (gfc_charlen_type_node)); } else { gfc_conv_expr_reference (&se, d->low); CONSTRUCTOR_APPEND_ELT (node, ss_string1[k], se.expr); CONSTRUCTOR_APPEND_ELT (node, ss_string1_len[k], se.string_length); } if (d->high == NULL) { CONSTRUCTOR_APPEND_ELT (node, ss_string2[k], null_pointer_node); CONSTRUCTOR_APPEND_ELT (node, ss_string2_len[k], build_zero_cst (gfc_charlen_type_node)); } else { gfc_init_se (&se, NULL); gfc_conv_expr_reference (&se, d->high); CONSTRUCTOR_APPEND_ELT (node, ss_string2[k], se.expr); CONSTRUCTOR_APPEND_ELT (node, ss_string2_len[k], se.string_length); } CONSTRUCTOR_APPEND_ELT (node, ss_target[k], build_int_cst (integer_type_node, d->n)); tmp = build_constructor (select_struct[k], node); CONSTRUCTOR_APPEND_ELT (inits, NULL_TREE, tmp); } type = build_array_type (select_struct[k], build_index_type (size_int (n-1))); init = build_constructor (type, inits); TREE_CONSTANT (init) = 1; TREE_STATIC (init) = 1; /* Create a static variable to hold the jump table. */ tmp = gfc_create_var (type, "jumptable"); TREE_CONSTANT (tmp) = 1; TREE_STATIC (tmp) = 1; TREE_READONLY (tmp) = 1; DECL_INITIAL (tmp) = init; init = tmp; /* Build the library call */ init = gfc_build_addr_expr (pvoid_type_node, init); if (code->expr1->ts.kind == 1) fndecl = gfor_fndecl_select_string; else if (code->expr1->ts.kind == 4) fndecl = gfor_fndecl_select_string_char4; else gcc_unreachable (); tmp = build_call_expr_loc (input_location, fndecl, 4, init, build_int_cst (gfc_charlen_type_node, n), expr1se.expr, expr1se.string_length); case_num = gfc_create_var (integer_type_node, "case_num"); gfc_add_modify (&block, case_num, tmp); gfc_add_block_to_block (&block, &expr1se.post); tmp = gfc_finish_block (&body); tmp = fold_build2_loc (input_location, SWITCH_EXPR, NULL_TREE, case_num, tmp); gfc_add_expr_to_block (&block, tmp); tmp = build1_v (LABEL_EXPR, end_label); gfc_add_expr_to_block (&block, tmp); return gfc_finish_block (&block); } /* Translate the three variants of the SELECT CASE construct. SELECT CASEs with INTEGER case expressions can be translated to an equivalent GENERIC switch statement, and for LOGICAL case expressions we build one or two if-else compares. SELECT CASEs with CHARACTER case expressions are a whole different story, because they don't exist in GENERIC. So we sort them and do a binary search at runtime. Fortran has no BREAK statement, and it does not allow jumps from one case block to another. That makes things a lot easier for the optimizers. */ tree gfc_trans_select (gfc_code * code) { stmtblock_t block; tree body; tree exit_label; gcc_assert (code && code->expr1); gfc_init_block (&block); /* Build the exit label and hang it in. */ exit_label = gfc_build_label_decl (NULL_TREE); code->exit_label = exit_label; /* Empty SELECT constructs are legal. */ if (code->block == NULL) body = build_empty_stmt (input_location); /* Select the correct translation function. */ else switch (code->expr1->ts.type) { case BT_LOGICAL: body = gfc_trans_logical_select (code); break; case BT_INTEGER: body = gfc_trans_integer_select (code); break; case BT_CHARACTER: body = gfc_trans_character_select (code); break; default: gfc_internal_error ("gfc_trans_select(): Bad type for case expr."); /* Not reached */ } /* Build everything together. */ gfc_add_expr_to_block (&block, body); gfc_add_expr_to_block (&block, build1_v (LABEL_EXPR, exit_label)); return gfc_finish_block (&block); } tree gfc_trans_select_type (gfc_code * code) { stmtblock_t block; tree body; tree exit_label; gcc_assert (code && code->expr1); gfc_init_block (&block); /* Build the exit label and hang it in. */ exit_label = gfc_build_label_decl (NULL_TREE); code->exit_label = exit_label; /* Empty SELECT constructs are legal. */ if (code->block == NULL) body = build_empty_stmt (input_location); else body = gfc_trans_select_type_cases (code); /* Build everything together. */ gfc_add_expr_to_block (&block, body); if (TREE_USED (exit_label)) gfc_add_expr_to_block (&block, build1_v (LABEL_EXPR, exit_label)); return gfc_finish_block (&block); } static tree gfc_trans_select_rank_cases (gfc_code * code) { gfc_code *c; gfc_case *cp; tree tmp; tree cond; tree low; tree sexpr; tree rank; tree rank_minus_one; tree minus_one; gfc_se se; gfc_se cse; stmtblock_t block; stmtblock_t body; bool def = false; gfc_start_block (&block); /* Calculate the switch expression. */ gfc_init_se (&se, NULL); gfc_conv_expr_descriptor (&se, code->expr1); rank = gfc_conv_descriptor_rank (se.expr); rank = gfc_evaluate_now (rank, &block); minus_one = build_int_cst (TREE_TYPE (rank), -1); tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, fold_convert (gfc_array_index_type, rank), build_int_cst (gfc_array_index_type, 1)); rank_minus_one = gfc_evaluate_now (tmp, &block); tmp = gfc_conv_descriptor_ubound_get (se.expr, rank_minus_one); cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, build_int_cst (TREE_TYPE (tmp), -1)); tmp = fold_build3_loc (input_location, COND_EXPR, TREE_TYPE (rank), cond, rank, minus_one); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, rank, build_int_cst (TREE_TYPE (rank), 0)); sexpr = fold_build3_loc (input_location, COND_EXPR, TREE_TYPE (rank), cond, rank, tmp); sexpr = gfc_evaluate_now (sexpr, &block); TREE_USED (code->exit_label) = 0; repeat: for (c = code->block; c; c = c->block) { cp = c->ext.block.case_list; /* Assume it's the default case. */ low = NULL_TREE; tmp = NULL_TREE; /* Put the default case at the end. */ if ((!def && !cp->low) || (def && cp->low)) continue; if (cp->low) { gfc_init_se (&cse, NULL); gfc_conv_expr_val (&cse, cp->low); gfc_add_block_to_block (&block, &cse.pre); low = cse.expr; } gfc_init_block (&body); /* Add the statements for this case. */ tmp = gfc_trans_code (c->next); gfc_add_expr_to_block (&body, tmp); /* Break to the end of the SELECT RANK construct. The default case just falls through. */ if (!def) { TREE_USED (code->exit_label) = 1; tmp = build1_v (GOTO_EXPR, code->exit_label); gfc_add_expr_to_block (&body, tmp); } tmp = gfc_finish_block (&body); if (low != NULL_TREE) { cond = fold_build2_loc (input_location, EQ_EXPR, TREE_TYPE (sexpr), sexpr, fold_convert (TREE_TYPE (sexpr), low)); 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); } if (!def) { def = true; goto repeat; } return gfc_finish_block (&block); } tree gfc_trans_select_rank (gfc_code * code) { stmtblock_t block; tree body; tree exit_label; gcc_assert (code && code->expr1); gfc_init_block (&block); /* Build the exit label and hang it in. */ exit_label = gfc_build_label_decl (NULL_TREE); code->exit_label = exit_label; /* Empty SELECT constructs are legal. */ if (code->block == NULL) body = build_empty_stmt (input_location); else body = gfc_trans_select_rank_cases (code); /* Build everything together. */ gfc_add_expr_to_block (&block, body); if (TREE_USED (exit_label)) gfc_add_expr_to_block (&block, build1_v (LABEL_EXPR, exit_label)); return gfc_finish_block (&block); } /* Traversal function to substitute a replacement symtree if the symbol in the expression is the same as that passed. f == 2 signals that that variable itself is not to be checked - only the references. This group of functions is used when the variable expression in a FORALL assignment has internal references. For example: FORALL (i = 1:4) p(p(i)) = i The only recourse here is to store a copy of 'p' for the index expression. */ static gfc_symtree *new_symtree; static gfc_symtree *old_symtree; static bool forall_replace (gfc_expr *expr, gfc_symbol *sym, int *f) { if (expr->expr_type != EXPR_VARIABLE) return false; if (*f == 2) *f = 1; else if (expr->symtree->n.sym == sym) expr->symtree = new_symtree; return false; } static void forall_replace_symtree (gfc_expr *e, gfc_symbol *sym, int f) { gfc_traverse_expr (e, sym, forall_replace, f); } static bool forall_restore (gfc_expr *expr, gfc_symbol *sym ATTRIBUTE_UNUSED, int *f ATTRIBUTE_UNUSED) { if (expr->expr_type != EXPR_VARIABLE) return false; if (expr->symtree == new_symtree) expr->symtree = old_symtree; return false; } static void forall_restore_symtree (gfc_expr *e) { gfc_traverse_expr (e, NULL, forall_restore, 0); } static void forall_make_variable_temp (gfc_code *c, stmtblock_t *pre, stmtblock_t *post) { gfc_se tse; gfc_se rse; gfc_expr *e; gfc_symbol *new_sym; gfc_symbol *old_sym; gfc_symtree *root; tree tmp; /* Build a copy of the lvalue. */ old_symtree = c->expr1->symtree; old_sym = old_symtree->n.sym; e = gfc_lval_expr_from_sym (old_sym); if (old_sym->attr.dimension) { gfc_init_se (&tse, NULL); gfc_conv_subref_array_arg (&tse, e, 0, INTENT_IN, false); gfc_add_block_to_block (pre, &tse.pre); gfc_add_block_to_block (post, &tse.post); tse.expr = build_fold_indirect_ref_loc (input_location, tse.expr); if (c->expr1->ref->u.ar.type != AR_SECTION) { /* Use the variable offset for the temporary. */ tmp = gfc_conv_array_offset (old_sym->backend_decl); gfc_conv_descriptor_offset_set (pre, tse.expr, tmp); } } else { gfc_init_se (&tse, NULL); gfc_init_se (&rse, NULL); gfc_conv_expr (&rse, e); if (e->ts.type == BT_CHARACTER) { tse.string_length = rse.string_length; tmp = gfc_get_character_type_len (gfc_default_character_kind, tse.string_length); tse.expr = gfc_conv_string_tmp (&tse, build_pointer_type (tmp), rse.string_length); gfc_add_block_to_block (pre, &tse.pre); gfc_add_block_to_block (post, &tse.post); } else { tmp = gfc_typenode_for_spec (&e->ts); tse.expr = gfc_create_var (tmp, "temp"); } tmp = gfc_trans_scalar_assign (&tse, &rse, e->ts, e->expr_type == EXPR_VARIABLE, false); gfc_add_expr_to_block (pre, tmp); } gfc_free_expr (e); /* Create a new symbol to represent the lvalue. */ new_sym = gfc_new_symbol (old_sym->name, NULL); new_sym->ts = old_sym->ts; new_sym->attr.referenced = 1; new_sym->attr.temporary = 1; new_sym->attr.dimension = old_sym->attr.dimension; new_sym->attr.flavor = old_sym->attr.flavor; /* Use the temporary as the backend_decl. */ new_sym->backend_decl = tse.expr; /* Create a fake symtree for it. */ root = NULL; new_symtree = gfc_new_symtree (&root, old_sym->name); new_symtree->n.sym = new_sym; gcc_assert (new_symtree == root); /* Go through the expression reference replacing the old_symtree with the new. */ forall_replace_symtree (c->expr1, old_sym, 2); /* Now we have made this temporary, we might as well use it for the right hand side. */ forall_replace_symtree (c->expr2, old_sym, 1); } /* Handles dependencies in forall assignments. */ static int check_forall_dependencies (gfc_code *c, stmtblock_t *pre, stmtblock_t *post) { gfc_ref *lref; gfc_ref *rref; int need_temp; gfc_symbol *lsym; lsym = c->expr1->symtree->n.sym; need_temp = gfc_check_dependency (c->expr1, c->expr2, 0); /* Now check for dependencies within the 'variable' expression itself. These are treated by making a complete copy of variable and changing all the references to it point to the copy instead. Note that the shallow copy of the variable will not suffice for derived types with pointer components. We therefore leave these to their own devices. */ if (lsym->ts.type == BT_DERIVED && lsym->ts.u.derived->attr.pointer_comp) return need_temp; new_symtree = NULL; if (find_forall_index (c->expr1, lsym, 2)) { forall_make_variable_temp (c, pre, post); need_temp = 0; } /* Substrings with dependencies are treated in the same way. */ if (c->expr1->ts.type == BT_CHARACTER && c->expr1->ref && c->expr2->expr_type == EXPR_VARIABLE && lsym == c->expr2->symtree->n.sym) { for (lref = c->expr1->ref; lref; lref = lref->next) if (lref->type == REF_SUBSTRING) break; for (rref = c->expr2->ref; rref; rref = rref->next) if (rref->type == REF_SUBSTRING) break; if (rref && lref && gfc_dep_compare_expr (rref->u.ss.start, lref->u.ss.start) < 0) { forall_make_variable_temp (c, pre, post); need_temp = 0; } } return need_temp; } static void cleanup_forall_symtrees (gfc_code *c) { forall_restore_symtree (c->expr1); forall_restore_symtree (c->expr2); free (new_symtree->n.sym); free (new_symtree); } /* Generate the loops for a FORALL block, specified by FORALL_TMP. BODY is the contents of the FORALL block/stmt to be iterated. MASK_FLAG indicates whether we should generate code to test the FORALLs mask array. OUTER is the loop header to be used for initializing mask indices. The generated loop format is: count = (end - start + step) / step loopvar = start while (1) { if (count <=0 ) goto end_of_loop loopvar += step count -- } end_of_loop: */ static tree gfc_trans_forall_loop (forall_info *forall_tmp, tree body, int mask_flag, stmtblock_t *outer) { int n, nvar; tree tmp; tree cond; stmtblock_t block; tree exit_label; tree count; tree var, start, end, step; iter_info *iter; /* Initialize the mask index outside the FORALL nest. */ if (mask_flag && forall_tmp->mask) gfc_add_modify (outer, forall_tmp->maskindex, gfc_index_zero_node); iter = forall_tmp->this_loop; nvar = forall_tmp->nvar; for (n = 0; n < nvar; n++) { var = iter->var; start = iter->start; end = iter->end; step = iter->step; exit_label = gfc_build_label_decl (NULL_TREE); TREE_USED (exit_label) = 1; /* The loop counter. */ count = gfc_create_var (TREE_TYPE (var), "count"); /* The body of the loop. */ gfc_init_block (&block); /* The exit condition. */ cond = fold_build2_loc (input_location, LE_EXPR, logical_type_node, count, build_int_cst (TREE_TYPE (count), 0)); /* PR 83064 means that we cannot use annot_expr_parallel_kind until the autoparallelizer can hande this. */ if (forall_tmp->do_concurrent) cond = build3 (ANNOTATE_EXPR, TREE_TYPE (cond), cond, build_int_cst (integer_type_node, annot_expr_ivdep_kind), integer_zero_node); 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 (&block, tmp); /* The main loop body. */ gfc_add_expr_to_block (&block, body); /* Increment the loop variable. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (var), var, step); gfc_add_modify (&block, var, tmp); /* Advance to the next mask element. Only do this for the innermost loop. */ if (n == 0 && mask_flag && forall_tmp->mask) { tree maskindex = forall_tmp->maskindex; tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, maskindex, gfc_index_one_node); gfc_add_modify (&block, maskindex, tmp); } /* Decrement the loop counter. */ tmp = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (var), count, build_int_cst (TREE_TYPE (var), 1)); gfc_add_modify (&block, count, tmp); body = gfc_finish_block (&block); /* Loop var initialization. */ gfc_init_block (&block); gfc_add_modify (&block, var, start); /* Initialize the loop counter. */ tmp = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (var), step, start); tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (var), end, tmp); tmp = fold_build2_loc (input_location, TRUNC_DIV_EXPR, TREE_TYPE (var), tmp, step); gfc_add_modify (&block, count, tmp); /* The loop expression. */ tmp = build1_v (LOOP_EXPR, body); gfc_add_expr_to_block (&block, tmp); /* The exit label. */ tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (&block, tmp); body = gfc_finish_block (&block); iter = iter->next; } return body; } /* Generate the body and loops according to MASK_FLAG. If MASK_FLAG is nonzero, the body is controlled by all masks in the forall nest. Otherwise, the innermost loop is not controlled by it's mask. This is used for initializing that mask. */ static tree gfc_trans_nested_forall_loop (forall_info * nested_forall_info, tree body, int mask_flag) { tree tmp; stmtblock_t header; forall_info *forall_tmp; tree mask, maskindex; gfc_start_block (&header); forall_tmp = nested_forall_info; while (forall_tmp != NULL) { /* Generate body with masks' control. */ if (mask_flag) { mask = forall_tmp->mask; maskindex = forall_tmp->maskindex; /* If a mask was specified make the assignment conditional. */ if (mask) { tmp = gfc_build_array_ref (mask, maskindex, NULL); body = build3_v (COND_EXPR, tmp, body, build_empty_stmt (input_location)); } } body = gfc_trans_forall_loop (forall_tmp, body, mask_flag, &header); forall_tmp = forall_tmp->prev_nest; mask_flag = 1; } gfc_add_expr_to_block (&header, body); return gfc_finish_block (&header); } /* Allocate data for holding a temporary array. Returns either a local temporary array or a pointer variable. */ static tree gfc_do_allocate (tree bytesize, tree size, tree * pdata, stmtblock_t * pblock, tree elem_type) { tree tmpvar; tree type; tree tmp; if (INTEGER_CST_P (size)) tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, size, gfc_index_one_node); else tmp = NULL_TREE; type = build_range_type (gfc_array_index_type, gfc_index_zero_node, tmp); type = build_array_type (elem_type, type); if (gfc_can_put_var_on_stack (bytesize) && INTEGER_CST_P (size)) { tmpvar = gfc_create_var (type, "temp"); *pdata = NULL_TREE; } else { tmpvar = gfc_create_var (build_pointer_type (type), "temp"); *pdata = convert (pvoid_type_node, tmpvar); tmp = gfc_call_malloc (pblock, TREE_TYPE (tmpvar), bytesize); gfc_add_modify (pblock, tmpvar, tmp); } return tmpvar; } /* Generate codes to copy the temporary to the actual lhs. */ static tree generate_loop_for_temp_to_lhs (gfc_expr *expr, tree tmp1, tree count3, tree count1, gfc_ss *lss, gfc_ss *rss, tree wheremask, bool invert) { stmtblock_t block, body1; gfc_loopinfo loop; gfc_se lse; gfc_se rse; tree tmp; tree wheremaskexpr; (void) rss; /* TODO: unused. */ gfc_start_block (&block); gfc_init_se (&rse, NULL); gfc_init_se (&lse, NULL); if (lss == gfc_ss_terminator) { gfc_init_block (&body1); gfc_conv_expr (&lse, expr); rse.expr = gfc_build_array_ref (tmp1, count1, NULL); } else { /* Initialize the loop. */ gfc_init_loopinfo (&loop); /* We may need LSS to determine the shape of the expression. */ gfc_add_ss_to_loop (&loop, lss); gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr->where); gfc_mark_ss_chain_used (lss, 1); /* Start the loop body. */ gfc_start_scalarized_body (&loop, &body1); /* Translate the expression. */ gfc_copy_loopinfo_to_se (&lse, &loop); lse.ss = lss; gfc_conv_expr (&lse, expr); /* Form the expression of the temporary. */ rse.expr = gfc_build_array_ref (tmp1, count1, NULL); } /* Use the scalar assignment. */ rse.string_length = lse.string_length; tmp = gfc_trans_scalar_assign (&lse, &rse, expr->ts, expr->expr_type == EXPR_VARIABLE, false); /* Form the mask expression according to the mask tree list. */ if (wheremask) { wheremaskexpr = gfc_build_array_ref (wheremask, count3, NULL); if (invert) wheremaskexpr = fold_build1_loc (input_location, TRUTH_NOT_EXPR, TREE_TYPE (wheremaskexpr), wheremaskexpr); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, wheremaskexpr, tmp, build_empty_stmt (input_location)); } gfc_add_expr_to_block (&body1, tmp); tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (count1), count1, gfc_index_one_node); gfc_add_modify (&body1, count1, tmp); if (lss == gfc_ss_terminator) gfc_add_block_to_block (&block, &body1); else { /* Increment count3. */ if (count3) { tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count3, gfc_index_one_node); gfc_add_modify (&body1, count3, tmp); } /* Generate the copying loops. */ gfc_trans_scalarizing_loops (&loop, &body1); gfc_add_block_to_block (&block, &loop.pre); gfc_add_block_to_block (&block, &loop.post); gfc_cleanup_loop (&loop); /* TODO: Reuse lss and rss when copying temp->lhs. Need to be careful as tree nodes in SS may not be valid in different scope. */ } tmp = gfc_finish_block (&block); return tmp; } /* Generate codes to copy rhs to the temporary. TMP1 is the address of temporary, LSS and RSS are formed in function compute_inner_temp_size(), and should not be freed. WHEREMASK is the conditional execution mask whose sense may be inverted by INVERT. */ static tree generate_loop_for_rhs_to_temp (gfc_expr *expr2, tree tmp1, tree count3, tree count1, gfc_ss *lss, gfc_ss *rss, tree wheremask, bool invert) { stmtblock_t block, body1; gfc_loopinfo loop; gfc_se lse; gfc_se rse; tree tmp; tree wheremaskexpr; gfc_start_block (&block); gfc_init_se (&rse, NULL); gfc_init_se (&lse, NULL); if (lss == gfc_ss_terminator) { gfc_init_block (&body1); gfc_conv_expr (&rse, expr2); lse.expr = gfc_build_array_ref (tmp1, count1, NULL); } else { /* Initialize the loop. */ gfc_init_loopinfo (&loop); /* We may need LSS to determine the shape of the expression. */ gfc_add_ss_to_loop (&loop, lss); gfc_add_ss_to_loop (&loop, rss); gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr2->where); gfc_mark_ss_chain_used (rss, 1); /* Start the loop body. */ gfc_start_scalarized_body (&loop, &body1); /* Translate the expression. */ gfc_copy_loopinfo_to_se (&rse, &loop); rse.ss = rss; gfc_conv_expr (&rse, expr2); /* Form the expression of the temporary. */ lse.expr = gfc_build_array_ref (tmp1, count1, NULL); } /* Use the scalar assignment. */ lse.string_length = rse.string_length; tmp = gfc_trans_scalar_assign (&lse, &rse, expr2->ts, expr2->expr_type == EXPR_VARIABLE, false); /* Form the mask expression according to the mask tree list. */ if (wheremask) { wheremaskexpr = gfc_build_array_ref (wheremask, count3, NULL); if (invert) wheremaskexpr = fold_build1_loc (input_location, TRUTH_NOT_EXPR, TREE_TYPE (wheremaskexpr), wheremaskexpr); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, wheremaskexpr, tmp, build_empty_stmt (input_location)); } gfc_add_expr_to_block (&body1, tmp); if (lss == gfc_ss_terminator) { gfc_add_block_to_block (&block, &body1); /* Increment count1. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (count1), count1, gfc_index_one_node); gfc_add_modify (&block, count1, tmp); } else { /* Increment count1. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count1, gfc_index_one_node); gfc_add_modify (&body1, count1, tmp); /* Increment count3. */ if (count3) { tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count3, gfc_index_one_node); gfc_add_modify (&body1, count3, tmp); } /* Generate the copying loops. */ gfc_trans_scalarizing_loops (&loop, &body1); gfc_add_block_to_block (&block, &loop.pre); gfc_add_block_to_block (&block, &loop.post); gfc_cleanup_loop (&loop); /* TODO: Reuse lss and rss when copying temp->lhs. Need to be careful as tree nodes in SS may not be valid in different scope. */ } tmp = gfc_finish_block (&block); return tmp; } /* Calculate the size of temporary needed in the assignment inside forall. LSS and RSS are filled in this function. */ static tree compute_inner_temp_size (gfc_expr *expr1, gfc_expr *expr2, stmtblock_t * pblock, gfc_ss **lss, gfc_ss **rss) { gfc_loopinfo loop; tree size; int i; int save_flag; tree tmp; *lss = gfc_walk_expr (expr1); *rss = NULL; size = gfc_index_one_node; if (*lss != gfc_ss_terminator) { gfc_init_loopinfo (&loop); /* Walk the RHS of the expression. */ *rss = gfc_walk_expr (expr2); if (*rss == gfc_ss_terminator) /* The rhs is scalar. Add a ss for the expression. */ *rss = gfc_get_scalar_ss (gfc_ss_terminator, expr2); /* Associate the SS with the loop. */ gfc_add_ss_to_loop (&loop, *lss); /* We don't actually need to add the rhs at this point, but it might make guessing the loop bounds a bit easier. */ gfc_add_ss_to_loop (&loop, *rss); /* We only want the shape of the expression, not rest of the junk generated by the scalarizer. */ loop.array_parameter = 1; /* Calculate the bounds of the scalarization. */ save_flag = gfc_option.rtcheck; gfc_option.rtcheck &= ~GFC_RTCHECK_BOUNDS; gfc_conv_ss_startstride (&loop); gfc_option.rtcheck = save_flag; gfc_conv_loop_setup (&loop, &expr2->where); /* Figure out how many elements we need. */ for (i = 0; i < loop.dimen; i++) { tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, gfc_index_one_node, loop.from[i]); tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, tmp, loop.to[i]); size = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, size, tmp); } gfc_add_block_to_block (pblock, &loop.pre); size = gfc_evaluate_now (size, pblock); gfc_add_block_to_block (pblock, &loop.post); /* TODO: write a function that cleans up a loopinfo without freeing the SS chains. Currently a NOP. */ } return size; } /* Calculate the overall iterator number of the nested forall construct. This routine actually calculates the number of times the body of the nested forall specified by NESTED_FORALL_INFO is executed and multiplies that by the expression INNER_SIZE. The BLOCK argument specifies the block in which to calculate the result, and the optional INNER_SIZE_BODY argument contains any statements that need to executed (inside the loop) to initialize or calculate INNER_SIZE. */ static tree compute_overall_iter_number (forall_info *nested_forall_info, tree inner_size, stmtblock_t *inner_size_body, stmtblock_t *block) { forall_info *forall_tmp = nested_forall_info; tree tmp, number; stmtblock_t body; /* We can eliminate the innermost unconditional loops with constant array bounds. */ if (INTEGER_CST_P (inner_size)) { while (forall_tmp && !forall_tmp->mask && INTEGER_CST_P (forall_tmp->size)) { inner_size = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, inner_size, forall_tmp->size); forall_tmp = forall_tmp->prev_nest; } /* If there are no loops left, we have our constant result. */ if (!forall_tmp) return inner_size; } /* Otherwise, create a temporary variable to compute the result. */ number = gfc_create_var (gfc_array_index_type, "num"); gfc_add_modify (block, number, gfc_index_zero_node); gfc_start_block (&body); if (inner_size_body) gfc_add_block_to_block (&body, inner_size_body); if (forall_tmp) tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, number, inner_size); else tmp = inner_size; gfc_add_modify (&body, number, tmp); tmp = gfc_finish_block (&body); /* Generate loops. */ if (forall_tmp != NULL) tmp = gfc_trans_nested_forall_loop (forall_tmp, tmp, 1); gfc_add_expr_to_block (block, tmp); return number; } /* Allocate temporary for forall construct. SIZE is the size of temporary needed. PTEMP1 is returned for space free. */ static tree allocate_temp_for_forall_nest_1 (tree type, tree size, stmtblock_t * block, tree * ptemp1) { tree bytesize; tree unit; tree tmp; unit = fold_convert (gfc_array_index_type, TYPE_SIZE_UNIT (type)); if (!integer_onep (unit)) bytesize = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, size, unit); else bytesize = size; *ptemp1 = NULL; tmp = gfc_do_allocate (bytesize, size, ptemp1, block, type); if (*ptemp1) tmp = build_fold_indirect_ref_loc (input_location, tmp); return tmp; } /* Allocate temporary for forall construct according to the information in nested_forall_info. INNER_SIZE is the size of temporary needed in the assignment inside forall. PTEMP1 is returned for space free. */ static tree allocate_temp_for_forall_nest (forall_info * nested_forall_info, tree type, tree inner_size, stmtblock_t * inner_size_body, stmtblock_t * block, tree * ptemp1) { tree size; /* Calculate the total size of temporary needed in forall construct. */ size = compute_overall_iter_number (nested_forall_info, inner_size, inner_size_body, block); return allocate_temp_for_forall_nest_1 (type, size, block, ptemp1); } /* Handle assignments inside forall which need temporary. forall (i=start:end:stride; maskexpr) e = f end forall (where e,f are arbitrary expressions possibly involving i and there is a dependency between e and f) Translates to: masktmp(:) = maskexpr(:) maskindex = 0; count1 = 0; num = 0; for (i = start; i <= end; i += stride) num += SIZE (f) count1 = 0; ALLOCATE (tmp(num)) for (i = start; i <= end; i += stride) { if (masktmp[maskindex++]) tmp[count1++] = f } maskindex = 0; count1 = 0; for (i = start; i <= end; i += stride) { if (masktmp[maskindex++]) e = tmp[count1++] } DEALLOCATE (tmp) */ static void gfc_trans_assign_need_temp (gfc_expr * expr1, gfc_expr * expr2, tree wheremask, bool invert, forall_info * nested_forall_info, stmtblock_t * block) { tree type; tree inner_size; gfc_ss *lss, *rss; tree count, count1; tree tmp, tmp1; tree ptemp1; stmtblock_t inner_size_body; /* Create vars. count1 is the current iterator number of the nested forall. */ count1 = gfc_create_var (gfc_array_index_type, "count1"); /* Count is the wheremask index. */ if (wheremask) { count = gfc_create_var (gfc_array_index_type, "count"); gfc_add_modify (block, count, gfc_index_zero_node); } else count = NULL; /* Initialize count1. */ gfc_add_modify (block, count1, gfc_index_zero_node); /* Calculate the size of temporary needed in the assignment. Return loop, lss and rss which are used in function generate_loop_for_rhs_to_temp(). */ /* The type of LHS. Used in function allocate_temp_for_forall_nest */ if (expr1->ts.type == BT_CHARACTER) { type = NULL; if (expr1->ref && expr1->ref->type == REF_SUBSTRING) { gfc_se ssse; gfc_init_se (&ssse, NULL); gfc_conv_expr (&ssse, expr1); type = gfc_get_character_type_len (gfc_default_character_kind, ssse.string_length); } else { if (!expr1->ts.u.cl->backend_decl) { gfc_se tse; gcc_assert (expr1->ts.u.cl->length); gfc_init_se (&tse, NULL); gfc_conv_expr (&tse, expr1->ts.u.cl->length); expr1->ts.u.cl->backend_decl = tse.expr; } type = gfc_get_character_type_len (gfc_default_character_kind, expr1->ts.u.cl->backend_decl); } } else type = gfc_typenode_for_spec (&expr1->ts); gfc_init_block (&inner_size_body); inner_size = compute_inner_temp_size (expr1, expr2, &inner_size_body, &lss, &rss); /* Allocate temporary for nested forall construct according to the information in nested_forall_info and inner_size. */ tmp1 = allocate_temp_for_forall_nest (nested_forall_info, type, inner_size, &inner_size_body, block, &ptemp1); /* Generate codes to copy rhs to the temporary . */ tmp = generate_loop_for_rhs_to_temp (expr2, tmp1, count, count1, lss, rss, wheremask, invert); /* Generate body and loops according to the information in nested_forall_info. */ tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (block, tmp); /* Reset count1. */ gfc_add_modify (block, count1, gfc_index_zero_node); /* Reset count. */ if (wheremask) gfc_add_modify (block, count, gfc_index_zero_node); /* TODO: Second call to compute_inner_temp_size to initialize lss and rss; there must be a better way. */ inner_size = compute_inner_temp_size (expr1, expr2, &inner_size_body, &lss, &rss); /* Generate codes to copy the temporary to lhs. */ tmp = generate_loop_for_temp_to_lhs (expr1, tmp1, count, count1, lss, rss, wheremask, invert); /* Generate body and loops according to the information in nested_forall_info. */ tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (block, tmp); if (ptemp1) { /* Free the temporary. */ tmp = gfc_call_free (ptemp1); gfc_add_expr_to_block (block, tmp); } } /* Translate pointer assignment inside FORALL which need temporary. */ static void gfc_trans_pointer_assign_need_temp (gfc_expr * expr1, gfc_expr * expr2, forall_info * nested_forall_info, stmtblock_t * block) { tree type; tree inner_size; gfc_ss *lss, *rss; gfc_se lse; gfc_se rse; gfc_array_info *info; gfc_loopinfo loop; tree desc; tree parm; tree parmtype; stmtblock_t body; tree count; tree tmp, tmp1, ptemp1; count = gfc_create_var (gfc_array_index_type, "count"); gfc_add_modify (block, count, gfc_index_zero_node); inner_size = gfc_index_one_node; lss = gfc_walk_expr (expr1); rss = gfc_walk_expr (expr2); if (lss == gfc_ss_terminator) { type = gfc_typenode_for_spec (&expr1->ts); type = build_pointer_type (type); /* Allocate temporary for nested forall construct according to the information in nested_forall_info and inner_size. */ tmp1 = allocate_temp_for_forall_nest (nested_forall_info, type, inner_size, NULL, block, &ptemp1); gfc_start_block (&body); gfc_init_se (&lse, NULL); lse.expr = gfc_build_array_ref (tmp1, count, NULL); gfc_init_se (&rse, NULL); rse.want_pointer = 1; gfc_conv_expr (&rse, expr2); gfc_add_block_to_block (&body, &rse.pre); gfc_add_modify (&body, lse.expr, fold_convert (TREE_TYPE (lse.expr), rse.expr)); gfc_add_block_to_block (&body, &rse.post); /* Increment count. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count, gfc_index_one_node); gfc_add_modify (&body, count, tmp); tmp = gfc_finish_block (&body); /* Generate body and loops according to the information in nested_forall_info. */ tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (block, tmp); /* Reset count. */ gfc_add_modify (block, count, gfc_index_zero_node); gfc_start_block (&body); gfc_init_se (&lse, NULL); gfc_init_se (&rse, NULL); rse.expr = gfc_build_array_ref (tmp1, count, NULL); lse.want_pointer = 1; gfc_conv_expr (&lse, expr1); gfc_add_block_to_block (&body, &lse.pre); gfc_add_modify (&body, lse.expr, rse.expr); gfc_add_block_to_block (&body, &lse.post); /* Increment count. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count, gfc_index_one_node); gfc_add_modify (&body, count, tmp); tmp = gfc_finish_block (&body); /* Generate body and loops according to the information in nested_forall_info. */ tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (block, tmp); } else { gfc_init_loopinfo (&loop); /* Associate the SS with the loop. */ gfc_add_ss_to_loop (&loop, rss); /* Setup the scalarizing loops and bounds. */ gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr2->where); info = &rss->info->data.array; desc = info->descriptor; /* Make a new descriptor. */ parmtype = gfc_get_element_type (TREE_TYPE (desc)); parmtype = gfc_get_array_type_bounds (parmtype, loop.dimen, 0, loop.from, loop.to, 1, GFC_ARRAY_UNKNOWN, true); /* Allocate temporary for nested forall construct. */ tmp1 = allocate_temp_for_forall_nest (nested_forall_info, parmtype, inner_size, NULL, block, &ptemp1); gfc_start_block (&body); gfc_init_se (&lse, NULL); lse.expr = gfc_build_array_ref (tmp1, count, NULL); lse.direct_byref = 1; gfc_conv_expr_descriptor (&lse, expr2); gfc_add_block_to_block (&body, &lse.pre); gfc_add_block_to_block (&body, &lse.post); /* Increment count. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count, gfc_index_one_node); gfc_add_modify (&body, count, tmp); tmp = gfc_finish_block (&body); /* Generate body and loops according to the information in nested_forall_info. */ tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (block, tmp); /* Reset count. */ gfc_add_modify (block, count, gfc_index_zero_node); parm = gfc_build_array_ref (tmp1, count, NULL); gfc_init_se (&lse, NULL); gfc_conv_expr_descriptor (&lse, expr1); gfc_add_modify (&lse.pre, lse.expr, parm); gfc_start_block (&body); gfc_add_block_to_block (&body, &lse.pre); gfc_add_block_to_block (&body, &lse.post); /* Increment count. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count, gfc_index_one_node); gfc_add_modify (&body, count, tmp); tmp = gfc_finish_block (&body); tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (block, tmp); } /* Free the temporary. */ if (ptemp1) { tmp = gfc_call_free (ptemp1); gfc_add_expr_to_block (block, tmp); } } /* FORALL and WHERE statements are really nasty, especially when you nest them. All the rhs of a forall assignment must be evaluated before the actual assignments are performed. Presumably this also applies to all the assignments in an inner where statement. */ /* Generate code for a FORALL statement. Any temporaries are allocated as a linear array, relying on the fact that we process in the same order in all loops. forall (i=start:end:stride; maskexpr) e = f g = h end forall (where e,f,g,h are arbitrary expressions possibly involving i) Translates to: count = ((end + 1 - start) / stride) masktmp(:) = maskexpr(:) maskindex = 0; for (i = start; i <= end; i += stride) { if (masktmp[maskindex++]) e = f } maskindex = 0; for (i = start; i <= end; i += stride) { if (masktmp[maskindex++]) g = h } Note that this code only works when there are no dependencies. Forall loop with array assignments and data dependencies are a real pain, because the size of the temporary cannot always be determined before the loop is executed. This problem is compounded by the presence of nested FORALL constructs. */ static tree gfc_trans_forall_1 (gfc_code * code, forall_info * nested_forall_info) { stmtblock_t pre; stmtblock_t post; stmtblock_t block; stmtblock_t body; tree *var; tree *start; tree *end; tree *step; gfc_expr **varexpr; tree tmp; tree assign; tree size; tree maskindex; tree mask; tree pmask; tree cycle_label = NULL_TREE; int n; int nvar; int need_temp; gfc_forall_iterator *fa; gfc_se se; gfc_code *c; gfc_saved_var *saved_vars; iter_info *this_forall; forall_info *info; bool need_mask; /* Do nothing if the mask is false. */ if (code->expr1 && code->expr1->expr_type == EXPR_CONSTANT && !code->expr1->value.logical) return build_empty_stmt (input_location); n = 0; /* Count the FORALL index number. */ for (fa = code->ext.forall_iterator; fa; fa = fa->next) n++; nvar = n; /* Allocate the space for var, start, end, step, varexpr. */ var = XCNEWVEC (tree, nvar); start = XCNEWVEC (tree, nvar); end = XCNEWVEC (tree, nvar); step = XCNEWVEC (tree, nvar); varexpr = XCNEWVEC (gfc_expr *, nvar); saved_vars = XCNEWVEC (gfc_saved_var, nvar); /* Allocate the space for info. */ info = XCNEW (forall_info); gfc_start_block (&pre); gfc_init_block (&post); gfc_init_block (&block); n = 0; for (fa = code->ext.forall_iterator; fa; fa = fa->next) { gfc_symbol *sym = fa->var->symtree->n.sym; /* Allocate space for this_forall. */ this_forall = XCNEW (iter_info); /* Create a temporary variable for the FORALL index. */ tmp = gfc_typenode_for_spec (&sym->ts); var[n] = gfc_create_var (tmp, sym->name); gfc_shadow_sym (sym, var[n], &saved_vars[n]); /* Record it in this_forall. */ this_forall->var = var[n]; /* Replace the index symbol's backend_decl with the temporary decl. */ sym->backend_decl = var[n]; /* Work out the start, end and stride for the loop. */ gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, fa->start); /* Record it in this_forall. */ this_forall->start = se.expr; gfc_add_block_to_block (&block, &se.pre); start[n] = se.expr; gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, fa->end); /* Record it in this_forall. */ this_forall->end = se.expr; gfc_make_safe_expr (&se); gfc_add_block_to_block (&block, &se.pre); end[n] = se.expr; gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, fa->stride); /* Record it in this_forall. */ this_forall->step = se.expr; gfc_make_safe_expr (&se); gfc_add_block_to_block (&block, &se.pre); step[n] = se.expr; /* Set the NEXT field of this_forall to NULL. */ this_forall->next = NULL; /* Link this_forall to the info construct. */ if (info->this_loop) { iter_info *iter_tmp = info->this_loop; while (iter_tmp->next != NULL) iter_tmp = iter_tmp->next; iter_tmp->next = this_forall; } else info->this_loop = this_forall; n++; } nvar = n; /* Calculate the size needed for the current forall level. */ size = gfc_index_one_node; for (n = 0; n < nvar; n++) { /* size = (end + step - start) / step. */ tmp = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (start[n]), step[n], start[n]); tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (end[n]), end[n], tmp); tmp = fold_build2_loc (input_location, FLOOR_DIV_EXPR, TREE_TYPE (tmp), tmp, step[n]); tmp = convert (gfc_array_index_type, tmp); size = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, size, tmp); } /* Record the nvar and size of current forall level. */ info->nvar = nvar; info->size = size; if (code->expr1) { /* If the mask is .true., consider the FORALL unconditional. */ if (code->expr1->expr_type == EXPR_CONSTANT && code->expr1->value.logical) need_mask = false; else need_mask = true; } else need_mask = false; /* First we need to allocate the mask. */ if (need_mask) { /* As the mask array can be very big, prefer compact boolean types. */ tree mask_type = gfc_get_logical_type (gfc_logical_kinds[0].kind); mask = allocate_temp_for_forall_nest (nested_forall_info, mask_type, size, NULL, &block, &pmask); maskindex = gfc_create_var_np (gfc_array_index_type, "mi"); /* Record them in the info structure. */ info->maskindex = maskindex; info->mask = mask; } else { /* No mask was specified. */ maskindex = NULL_TREE; mask = pmask = NULL_TREE; } /* Link the current forall level to nested_forall_info. */ info->prev_nest = nested_forall_info; nested_forall_info = info; /* Copy the mask into a temporary variable if required. For now we assume a mask temporary is needed. */ if (need_mask) { /* As the mask array can be very big, prefer compact boolean types. */ tree mask_type = gfc_get_logical_type (gfc_logical_kinds[0].kind); gfc_add_modify (&block, maskindex, gfc_index_zero_node); /* Start of mask assignment loop body. */ gfc_start_block (&body); /* Evaluate the mask expression. */ gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, code->expr1); gfc_add_block_to_block (&body, &se.pre); /* Store the mask. */ se.expr = convert (mask_type, se.expr); tmp = gfc_build_array_ref (mask, maskindex, NULL); gfc_add_modify (&body, tmp, se.expr); /* Advance to the next mask element. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, maskindex, gfc_index_one_node); gfc_add_modify (&body, maskindex, tmp); /* Generate the loops. */ tmp = gfc_finish_block (&body); tmp = gfc_trans_nested_forall_loop (info, tmp, 0); gfc_add_expr_to_block (&block, tmp); } if (code->op == EXEC_DO_CONCURRENT) { gfc_init_block (&body); cycle_label = gfc_build_label_decl (NULL_TREE); code->cycle_label = cycle_label; tmp = gfc_trans_code (code->block->next); gfc_add_expr_to_block (&body, tmp); if (TREE_USED (cycle_label)) { tmp = build1_v (LABEL_EXPR, cycle_label); gfc_add_expr_to_block (&body, tmp); } tmp = gfc_finish_block (&body); nested_forall_info->do_concurrent = true; tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (&block, tmp); goto done; } c = code->block->next; /* TODO: loop merging in FORALL statements. */ /* Now that we've got a copy of the mask, generate the assignment loops. */ while (c) { switch (c->op) { case EXEC_ASSIGN: /* A scalar or array assignment. DO the simple check for lhs to rhs dependencies. These make a temporary for the rhs and form a second forall block to copy to variable. */ need_temp = check_forall_dependencies(c, &pre, &post); /* Temporaries due to array assignment data dependencies introduce no end of problems. */ if (need_temp || flag_test_forall_temp) gfc_trans_assign_need_temp (c->expr1, c->expr2, NULL, false, nested_forall_info, &block); else { /* Use the normal assignment copying routines. */ assign = gfc_trans_assignment (c->expr1, c->expr2, false, true); /* Generate body and loops. */ tmp = gfc_trans_nested_forall_loop (nested_forall_info, assign, 1); gfc_add_expr_to_block (&block, tmp); } /* Cleanup any temporary symtrees that have been made to deal with dependencies. */ if (new_symtree) cleanup_forall_symtrees (c); break; case EXEC_WHERE: /* Translate WHERE or WHERE construct nested in FORALL. */ gfc_trans_where_2 (c, NULL, false, nested_forall_info, &block); break; /* Pointer assignment inside FORALL. */ case EXEC_POINTER_ASSIGN: need_temp = gfc_check_dependency (c->expr1, c->expr2, 0); /* Avoid cases where a temporary would never be needed and where the temp code is guaranteed to fail. */ if (need_temp || (flag_test_forall_temp && c->expr2->expr_type != EXPR_CONSTANT && c->expr2->expr_type != EXPR_NULL)) gfc_trans_pointer_assign_need_temp (c->expr1, c->expr2, nested_forall_info, &block); else { /* Use the normal assignment copying routines. */ assign = gfc_trans_pointer_assignment (c->expr1, c->expr2); /* Generate body and loops. */ tmp = gfc_trans_nested_forall_loop (nested_forall_info, assign, 1); gfc_add_expr_to_block (&block, tmp); } break; case EXEC_FORALL: tmp = gfc_trans_forall_1 (c, nested_forall_info); gfc_add_expr_to_block (&block, tmp); break; /* Explicit subroutine calls are prevented by the frontend but interface assignments can legitimately produce them. */ case EXEC_ASSIGN_CALL: assign = gfc_trans_call (c, true, NULL_TREE, NULL_TREE, false); tmp = gfc_trans_nested_forall_loop (nested_forall_info, assign, 1); gfc_add_expr_to_block (&block, tmp); break; default: gcc_unreachable (); } c = c->next; } done: /* Restore the original index variables. */ for (fa = code->ext.forall_iterator, n = 0; fa; fa = fa->next, n++) gfc_restore_sym (fa->var->symtree->n.sym, &saved_vars[n]); /* Free the space for var, start, end, step, varexpr. */ free (var); free (start); free (end); free (step); free (varexpr); free (saved_vars); for (this_forall = info->this_loop; this_forall;) { iter_info *next = this_forall->next; free (this_forall); this_forall = next; } /* Free the space for this forall_info. */ free (info); if (pmask) { /* Free the temporary for the mask. */ tmp = gfc_call_free (pmask); gfc_add_expr_to_block (&block, tmp); } if (maskindex) pushdecl (maskindex); gfc_add_block_to_block (&pre, &block); gfc_add_block_to_block (&pre, &post); return gfc_finish_block (&pre); } /* Translate the FORALL statement or construct. */ tree gfc_trans_forall (gfc_code * code) { return gfc_trans_forall_1 (code, NULL); } /* Translate the DO CONCURRENT construct. */ tree gfc_trans_do_concurrent (gfc_code * code) { return gfc_trans_forall_1 (code, NULL); } /* Evaluate the WHERE mask expression, copy its value to a temporary. If the WHERE construct is nested in FORALL, compute the overall temporary needed by the WHERE mask expression multiplied by the iterator number of the nested forall. ME is the WHERE mask expression. MASK is the current execution mask upon input, whose sense may or may not be inverted as specified by the INVERT argument. CMASK is the updated execution mask on output, or NULL if not required. PMASK is the pending execution mask on output, or NULL if not required. BLOCK is the block in which to place the condition evaluation loops. */ static void gfc_evaluate_where_mask (gfc_expr * me, forall_info * nested_forall_info, tree mask, bool invert, tree cmask, tree pmask, tree mask_type, stmtblock_t * block) { tree tmp, tmp1; gfc_ss *lss, *rss; gfc_loopinfo loop; stmtblock_t body, body1; tree count, cond, mtmp; gfc_se lse, rse; gfc_init_loopinfo (&loop); lss = gfc_walk_expr (me); rss = gfc_walk_expr (me); /* Variable to index the temporary. */ count = gfc_create_var (gfc_array_index_type, "count"); /* Initialize count. */ gfc_add_modify (block, count, gfc_index_zero_node); gfc_start_block (&body); gfc_init_se (&rse, NULL); gfc_init_se (&lse, NULL); if (lss == gfc_ss_terminator) { gfc_init_block (&body1); } else { /* Initialize the loop. */ gfc_init_loopinfo (&loop); /* We may need LSS to determine the shape of the expression. */ gfc_add_ss_to_loop (&loop, lss); gfc_add_ss_to_loop (&loop, rss); gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &me->where); gfc_mark_ss_chain_used (rss, 1); /* Start the loop body. */ gfc_start_scalarized_body (&loop, &body1); /* Translate the expression. */ gfc_copy_loopinfo_to_se (&rse, &loop); rse.ss = rss; gfc_conv_expr (&rse, me); } /* Variable to evaluate mask condition. */ cond = gfc_create_var (mask_type, "cond"); if (mask && (cmask || pmask)) mtmp = gfc_create_var (mask_type, "mask"); else mtmp = NULL_TREE; gfc_add_block_to_block (&body1, &lse.pre); gfc_add_block_to_block (&body1, &rse.pre); gfc_add_modify (&body1, cond, fold_convert (mask_type, rse.expr)); if (mask && (cmask || pmask)) { tmp = gfc_build_array_ref (mask, count, NULL); if (invert) tmp = fold_build1_loc (input_location, TRUTH_NOT_EXPR, mask_type, tmp); gfc_add_modify (&body1, mtmp, tmp); } if (cmask) { tmp1 = gfc_build_array_ref (cmask, count, NULL); tmp = cond; if (mask) tmp = fold_build2_loc (input_location, TRUTH_AND_EXPR, mask_type, mtmp, tmp); gfc_add_modify (&body1, tmp1, tmp); } if (pmask) { tmp1 = gfc_build_array_ref (pmask, count, NULL); tmp = fold_build1_loc (input_location, TRUTH_NOT_EXPR, mask_type, cond); if (mask) tmp = fold_build2_loc (input_location, TRUTH_AND_EXPR, mask_type, mtmp, tmp); gfc_add_modify (&body1, tmp1, tmp); } gfc_add_block_to_block (&body1, &lse.post); gfc_add_block_to_block (&body1, &rse.post); if (lss == gfc_ss_terminator) { gfc_add_block_to_block (&body, &body1); } else { /* Increment count. */ tmp1 = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count, gfc_index_one_node); gfc_add_modify (&body1, count, tmp1); /* Generate the copying loops. */ gfc_trans_scalarizing_loops (&loop, &body1); gfc_add_block_to_block (&body, &loop.pre); gfc_add_block_to_block (&body, &loop.post); gfc_cleanup_loop (&loop); /* TODO: Reuse lss and rss when copying temp->lhs. Need to be careful as tree nodes in SS may not be valid in different scope. */ } tmp1 = gfc_finish_block (&body); /* If the WHERE construct is inside FORALL, fill the full temporary. */ if (nested_forall_info != NULL) tmp1 = gfc_trans_nested_forall_loop (nested_forall_info, tmp1, 1); gfc_add_expr_to_block (block, tmp1); } /* Translate an assignment statement in a WHERE statement or construct statement. The MASK expression is used to control which elements of EXPR1 shall be assigned. The sense of MASK is specified by INVERT. */ static tree gfc_trans_where_assign (gfc_expr *expr1, gfc_expr *expr2, tree mask, bool invert, tree count1, tree count2, gfc_code *cnext) { gfc_se lse; gfc_se rse; gfc_ss *lss; gfc_ss *lss_section; gfc_ss *rss; gfc_loopinfo loop; tree tmp; stmtblock_t block; stmtblock_t body; tree index, maskexpr; /* A defined assignment. */ if (cnext && cnext->resolved_sym) return gfc_trans_call (cnext, true, mask, count1, invert); #if 0 /* TODO: handle this special case. Special case a single function returning an array. */ if (expr2->expr_type == EXPR_FUNCTION && expr2->rank > 0) { tmp = gfc_trans_arrayfunc_assign (expr1, expr2); if (tmp) return tmp; } #endif /* Assignment of the form lhs = rhs. */ gfc_start_block (&block); gfc_init_se (&lse, NULL); gfc_init_se (&rse, NULL); /* Walk the lhs. */ lss = gfc_walk_expr (expr1); rss = NULL; /* In each where-assign-stmt, the mask-expr and the variable being defined shall be arrays of the same shape. */ gcc_assert (lss != gfc_ss_terminator); /* The assignment needs scalarization. */ lss_section = lss; /* Find a non-scalar SS from the lhs. */ while (lss_section != gfc_ss_terminator && lss_section->info->type != GFC_SS_SECTION) lss_section = lss_section->next; gcc_assert (lss_section != gfc_ss_terminator); /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); /* Walk the rhs. */ rss = gfc_walk_expr (expr2); if (rss == gfc_ss_terminator) { /* The rhs is scalar. Add a ss for the expression. */ rss = gfc_get_scalar_ss (gfc_ss_terminator, expr2); rss->info->where = 1; } /* Associate the SS with the loop. */ gfc_add_ss_to_loop (&loop, lss); gfc_add_ss_to_loop (&loop, rss); /* Calculate the bounds of the scalarization. */ gfc_conv_ss_startstride (&loop); /* Resolve any data dependencies in the statement. */ gfc_conv_resolve_dependencies (&loop, lss_section, rss); /* Setup the scalarizing loops. */ gfc_conv_loop_setup (&loop, &expr2->where); /* Setup the gfc_se structures. */ gfc_copy_loopinfo_to_se (&lse, &loop); gfc_copy_loopinfo_to_se (&rse, &loop); rse.ss = rss; gfc_mark_ss_chain_used (rss, 1); if (loop.temp_ss == NULL) { lse.ss = lss; gfc_mark_ss_chain_used (lss, 1); } else { lse.ss = loop.temp_ss; gfc_mark_ss_chain_used (lss, 3); gfc_mark_ss_chain_used (loop.temp_ss, 3); } /* Start the scalarized loop body. */ gfc_start_scalarized_body (&loop, &body); /* Translate the expression. */ gfc_conv_expr (&rse, expr2); if (lss != gfc_ss_terminator && loop.temp_ss != NULL) gfc_conv_tmp_array_ref (&lse); else gfc_conv_expr (&lse, expr1); /* Form the mask expression according to the mask. */ index = count1; maskexpr = gfc_build_array_ref (mask, index, NULL); if (invert) maskexpr = fold_build1_loc (input_location, TRUTH_NOT_EXPR, TREE_TYPE (maskexpr), maskexpr); /* Use the scalar assignment as is. */ tmp = gfc_trans_scalar_assign (&lse, &rse, expr1->ts, false, loop.temp_ss == NULL); tmp = build3_v (COND_EXPR, maskexpr, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&body, tmp); if (lss == gfc_ss_terminator) { /* Increment count1. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count1, gfc_index_one_node); gfc_add_modify (&body, count1, tmp); /* Use the scalar assignment as is. */ gfc_add_block_to_block (&block, &body); } else { gcc_assert (lse.ss == gfc_ss_terminator && rse.ss == gfc_ss_terminator); if (loop.temp_ss != NULL) { /* Increment count1 before finish the main body of a scalarized expression. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count1, gfc_index_one_node); gfc_add_modify (&body, count1, tmp); gfc_trans_scalarized_loop_boundary (&loop, &body); /* We need to copy the temporary to the actual lhs. */ gfc_init_se (&lse, NULL); gfc_init_se (&rse, NULL); gfc_copy_loopinfo_to_se (&lse, &loop); gfc_copy_loopinfo_to_se (&rse, &loop); rse.ss = loop.temp_ss; lse.ss = lss; gfc_conv_tmp_array_ref (&rse); gfc_conv_expr (&lse, expr1); gcc_assert (lse.ss == gfc_ss_terminator && rse.ss == gfc_ss_terminator); /* Form the mask expression according to the mask tree list. */ index = count2; maskexpr = gfc_build_array_ref (mask, index, NULL); if (invert) maskexpr = fold_build1_loc (input_location, TRUTH_NOT_EXPR, TREE_TYPE (maskexpr), maskexpr); /* Use the scalar assignment as is. */ tmp = gfc_trans_scalar_assign (&lse, &rse, expr1->ts, false, true); tmp = build3_v (COND_EXPR, maskexpr, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&body, tmp); /* Increment count2. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count2, gfc_index_one_node); gfc_add_modify (&body, count2, tmp); } else { /* Increment count1. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, count1, gfc_index_one_node); gfc_add_modify (&body, count1, tmp); } /* Generate the copying loops. */ gfc_trans_scalarizing_loops (&loop, &body); /* Wrap the whole thing up. */ gfc_add_block_to_block (&block, &loop.pre); gfc_add_block_to_block (&block, &loop.post); gfc_cleanup_loop (&loop); } return gfc_finish_block (&block); } /* Translate the WHERE construct or statement. This function can be called iteratively to translate the nested WHERE construct or statement. MASK is the control mask. */ static void gfc_trans_where_2 (gfc_code * code, tree mask, bool invert, forall_info * nested_forall_info, stmtblock_t * block) { stmtblock_t inner_size_body; tree inner_size, size; gfc_ss *lss, *rss; tree mask_type; gfc_expr *expr1; gfc_expr *expr2; gfc_code *cblock; gfc_code *cnext; tree tmp; tree cond; tree count1, count2; bool need_cmask; bool need_pmask; int need_temp; tree pcmask = NULL_TREE; tree ppmask = NULL_TREE; tree cmask = NULL_TREE; tree pmask = NULL_TREE; gfc_actual_arglist *arg; /* the WHERE statement or the WHERE construct statement. */ cblock = code->block; /* As the mask array can be very big, prefer compact boolean types. */ mask_type = gfc_get_logical_type (gfc_logical_kinds[0].kind); /* Determine which temporary masks are needed. */ if (!cblock->block) { /* One clause: No ELSEWHEREs. */ need_cmask = (cblock->next != 0); need_pmask = false; } else if (cblock->block->block) { /* Three or more clauses: Conditional ELSEWHEREs. */ need_cmask = true; need_pmask = true; } else if (cblock->next) { /* Two clauses, the first non-empty. */ need_cmask = true; need_pmask = (mask != NULL_TREE && cblock->block->next != 0); } else if (!cblock->block->next) { /* Two clauses, both empty. */ need_cmask = false; need_pmask = false; } /* Two clauses, the first empty, the second non-empty. */ else if (mask) { need_cmask = (cblock->block->expr1 != 0); need_pmask = true; } else { need_cmask = true; need_pmask = false; } if (need_cmask || need_pmask) { /* Calculate the size of temporary needed by the mask-expr. */ gfc_init_block (&inner_size_body); inner_size = compute_inner_temp_size (cblock->expr1, cblock->expr1, &inner_size_body, &lss, &rss); gfc_free_ss_chain (lss); gfc_free_ss_chain (rss); /* Calculate the total size of temporary needed. */ size = compute_overall_iter_number (nested_forall_info, inner_size, &inner_size_body, block); /* Check whether the size is negative. */ cond = fold_build2_loc (input_location, LE_EXPR, logical_type_node, size, gfc_index_zero_node); size = fold_build3_loc (input_location, COND_EXPR, gfc_array_index_type, cond, gfc_index_zero_node, size); size = gfc_evaluate_now (size, block); /* Allocate temporary for WHERE mask if needed. */ if (need_cmask) cmask = allocate_temp_for_forall_nest_1 (mask_type, size, block, &pcmask); /* Allocate temporary for !mask if needed. */ if (need_pmask) pmask = allocate_temp_for_forall_nest_1 (mask_type, size, block, &ppmask); } while (cblock) { /* Each time around this loop, the where clause is conditional on the value of mask and invert, which are updated at the bottom of the loop. */ /* Has mask-expr. */ if (cblock->expr1) { /* Ensure that the WHERE mask will be evaluated exactly once. If there are no statements in this WHERE/ELSEWHERE clause, then we don't need to update the control mask (cmask). If this is the last clause of the WHERE construct, then we don't need to update the pending control mask (pmask). */ if (mask) gfc_evaluate_where_mask (cblock->expr1, nested_forall_info, mask, invert, cblock->next ? cmask : NULL_TREE, cblock->block ? pmask : NULL_TREE, mask_type, block); else gfc_evaluate_where_mask (cblock->expr1, nested_forall_info, NULL_TREE, false, (cblock->next || cblock->block) ? cmask : NULL_TREE, NULL_TREE, mask_type, block); invert = false; } /* It's a final elsewhere-stmt. No mask-expr is present. */ else cmask = mask; /* The body of this where clause are controlled by cmask with sense specified by invert. */ /* Get the assignment statement of a WHERE statement, or the first statement in where-body-construct of a WHERE construct. */ cnext = cblock->next; while (cnext) { switch (cnext->op) { /* WHERE assignment statement. */ case EXEC_ASSIGN_CALL: arg = cnext->ext.actual; expr1 = expr2 = NULL; for (; arg; arg = arg->next) { if (!arg->expr) continue; if (expr1 == NULL) expr1 = arg->expr; else expr2 = arg->expr; } goto evaluate; case EXEC_ASSIGN: expr1 = cnext->expr1; expr2 = cnext->expr2; evaluate: if (nested_forall_info != NULL) { need_temp = gfc_check_dependency (expr1, expr2, 0); if ((need_temp || flag_test_forall_temp) && cnext->op != EXEC_ASSIGN_CALL) gfc_trans_assign_need_temp (expr1, expr2, cmask, invert, nested_forall_info, block); else { /* Variables to control maskexpr. */ count1 = gfc_create_var (gfc_array_index_type, "count1"); count2 = gfc_create_var (gfc_array_index_type, "count2"); gfc_add_modify (block, count1, gfc_index_zero_node); gfc_add_modify (block, count2, gfc_index_zero_node); tmp = gfc_trans_where_assign (expr1, expr2, cmask, invert, count1, count2, cnext); tmp = gfc_trans_nested_forall_loop (nested_forall_info, tmp, 1); gfc_add_expr_to_block (block, tmp); } } else { /* Variables to control maskexpr. */ count1 = gfc_create_var (gfc_array_index_type, "count1"); count2 = gfc_create_var (gfc_array_index_type, "count2"); gfc_add_modify (block, count1, gfc_index_zero_node); gfc_add_modify (block, count2, gfc_index_zero_node); tmp = gfc_trans_where_assign (expr1, expr2, cmask, invert, count1, count2, cnext); gfc_add_expr_to_block (block, tmp); } break; /* WHERE or WHERE construct is part of a where-body-construct. */ case EXEC_WHERE: gfc_trans_where_2 (cnext, cmask, invert, nested_forall_info, block); break; default: gcc_unreachable (); } /* The next statement within the same where-body-construct. */ cnext = cnext->next; } /* The next masked-elsewhere-stmt, elsewhere-stmt, or end-where-stmt. */ cblock = cblock->block; if (mask == NULL_TREE) { /* If we're the initial WHERE, we can simply invert the sense of the current mask to obtain the "mask" for the remaining ELSEWHEREs. */ invert = true; mask = cmask; } else { /* Otherwise, for nested WHERE's we need to use the pending mask. */ invert = false; mask = pmask; } } /* If we allocated a pending mask array, deallocate it now. */ if (ppmask) { tmp = gfc_call_free (ppmask); gfc_add_expr_to_block (block, tmp); } /* If we allocated a current mask array, deallocate it now. */ if (pcmask) { tmp = gfc_call_free (pcmask); gfc_add_expr_to_block (block, tmp); } } /* Translate a simple WHERE construct or statement without dependencies. CBLOCK is the "then" clause of the WHERE statement, where CBLOCK->EXPR is the mask condition, and EBLOCK if non-NULL is the "else" clause. Currently both CBLOCK and EBLOCK are restricted to single assignments. */ static tree gfc_trans_where_3 (gfc_code * cblock, gfc_code * eblock) { stmtblock_t block, body; gfc_expr *cond, *tdst, *tsrc, *edst, *esrc; tree tmp, cexpr, tstmt, estmt; gfc_ss *css, *tdss, *tsss; gfc_se cse, tdse, tsse, edse, esse; gfc_loopinfo loop; gfc_ss *edss = 0; gfc_ss *esss = 0; bool maybe_workshare = false; /* Allow the scalarizer to workshare simple where loops. */ if ((ompws_flags & (OMPWS_WORKSHARE_FLAG | OMPWS_SCALARIZER_BODY)) == OMPWS_WORKSHARE_FLAG) { maybe_workshare = true; ompws_flags |= OMPWS_SCALARIZER_WS | OMPWS_SCALARIZER_BODY; } cond = cblock->expr1; tdst = cblock->next->expr1; tsrc = cblock->next->expr2; edst = eblock ? eblock->next->expr1 : NULL; esrc = eblock ? eblock->next->expr2 : NULL; gfc_start_block (&block); gfc_init_loopinfo (&loop); /* Handle the condition. */ gfc_init_se (&cse, NULL); css = gfc_walk_expr (cond); gfc_add_ss_to_loop (&loop, css); /* Handle the then-clause. */ gfc_init_se (&tdse, NULL); gfc_init_se (&tsse, NULL); tdss = gfc_walk_expr (tdst); tsss = gfc_walk_expr (tsrc); if (tsss == gfc_ss_terminator) { tsss = gfc_get_scalar_ss (gfc_ss_terminator, tsrc); tsss->info->where = 1; } gfc_add_ss_to_loop (&loop, tdss); gfc_add_ss_to_loop (&loop, tsss); if (eblock) { /* Handle the else clause. */ gfc_init_se (&edse, NULL); gfc_init_se (&esse, NULL); edss = gfc_walk_expr (edst); esss = gfc_walk_expr (esrc); if (esss == gfc_ss_terminator) { esss = gfc_get_scalar_ss (gfc_ss_terminator, esrc); esss->info->where = 1; } gfc_add_ss_to_loop (&loop, edss); gfc_add_ss_to_loop (&loop, esss); } gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &tdst->where); gfc_mark_ss_chain_used (css, 1); gfc_mark_ss_chain_used (tdss, 1); gfc_mark_ss_chain_used (tsss, 1); if (eblock) { gfc_mark_ss_chain_used (edss, 1); gfc_mark_ss_chain_used (esss, 1); } gfc_start_scalarized_body (&loop, &body); gfc_copy_loopinfo_to_se (&cse, &loop); gfc_copy_loopinfo_to_se (&tdse, &loop); gfc_copy_loopinfo_to_se (&tsse, &loop); cse.ss = css; tdse.ss = tdss; tsse.ss = tsss; if (eblock) { gfc_copy_loopinfo_to_se (&edse, &loop); gfc_copy_loopinfo_to_se (&esse, &loop); edse.ss = edss; esse.ss = esss; } gfc_conv_expr (&cse, cond); gfc_add_block_to_block (&body, &cse.pre); cexpr = cse.expr; gfc_conv_expr (&tsse, tsrc); if (tdss != gfc_ss_terminator && loop.temp_ss != NULL) gfc_conv_tmp_array_ref (&tdse); else gfc_conv_expr (&tdse, tdst); if (eblock) { gfc_conv_expr (&esse, esrc); if (edss != gfc_ss_terminator && loop.temp_ss != NULL) gfc_conv_tmp_array_ref (&edse); else gfc_conv_expr (&edse, edst); } tstmt = gfc_trans_scalar_assign (&tdse, &tsse, tdst->ts, false, true); estmt = eblock ? gfc_trans_scalar_assign (&edse, &esse, edst->ts, false, true) : build_empty_stmt (input_location); tmp = build3_v (COND_EXPR, cexpr, tstmt, estmt); gfc_add_expr_to_block (&body, tmp); gfc_add_block_to_block (&body, &cse.post); if (maybe_workshare) ompws_flags &= ~OMPWS_SCALARIZER_BODY; gfc_trans_scalarizing_loops (&loop, &body); gfc_add_block_to_block (&block, &loop.pre); gfc_add_block_to_block (&block, &loop.post); gfc_cleanup_loop (&loop); return gfc_finish_block (&block); } /* As the WHERE or WHERE construct statement can be nested, we call gfc_trans_where_2 to do the translation, and pass the initial NULL values for both the control mask and the pending control mask. */ tree gfc_trans_where (gfc_code * code) { stmtblock_t block; gfc_code *cblock; gfc_code *eblock; cblock = code->block; if (cblock->next && cblock->next->op == EXEC_ASSIGN && !cblock->next->next) { eblock = cblock->block; if (!eblock) { /* A simple "WHERE (cond) x = y" statement or block is dependence free if cond is not dependent upon writing x, and the source y is unaffected by the destination x. */ if (!gfc_check_dependency (cblock->next->expr1, cblock->expr1, 0) && !gfc_check_dependency (cblock->next->expr1, cblock->next->expr2, 0)) return gfc_trans_where_3 (cblock, NULL); } else if (!eblock->expr1 && !eblock->block && eblock->next && eblock->next->op == EXEC_ASSIGN && !eblock->next->next) { /* A simple "WHERE (cond) x1 = y1 ELSEWHERE x2 = y2 ENDWHERE" block is dependence free if cond is not dependent on writes to x1 and x2, y1 is not dependent on writes to x2, and y2 is not dependent on writes to x1, and both y's are not dependent upon their own x's. In addition to this, the final two dependency checks below exclude all but the same array reference if the where and elswhere destinations are the same. In short, this is VERY conservative and this is needed because the two loops, required by the standard are coalesced in gfc_trans_where_3. */ if (!gfc_check_dependency (cblock->next->expr1, cblock->expr1, 0) && !gfc_check_dependency (eblock->next->expr1, cblock->expr1, 0) && !gfc_check_dependency (cblock->next->expr1, eblock->next->expr2, 1) && !gfc_check_dependency (eblock->next->expr1, cblock->next->expr2, 1) && !gfc_check_dependency (cblock->next->expr1, cblock->next->expr2, 1) && !gfc_check_dependency (eblock->next->expr1, eblock->next->expr2, 1) && !gfc_check_dependency (cblock->next->expr1, eblock->next->expr1, 0) && !gfc_check_dependency (eblock->next->expr1, cblock->next->expr1, 0)) return gfc_trans_where_3 (cblock, eblock); } } gfc_start_block (&block); gfc_trans_where_2 (code, NULL, false, NULL, &block); return gfc_finish_block (&block); } /* CYCLE a DO loop. The label decl has already been created by gfc_trans_do(), it's in TREE_PURPOSE (backend_decl) of the gfc_code node at the head of the loop. We must mark the label as used. */ tree gfc_trans_cycle (gfc_code * code) { tree cycle_label; cycle_label = code->ext.which_construct->cycle_label; gcc_assert (cycle_label); TREE_USED (cycle_label) = 1; return build1_v (GOTO_EXPR, cycle_label); } /* EXIT a DO loop. Similar to CYCLE, but now the label is in TREE_VALUE (backend_decl) of the gfc_code node at the head of the loop. */ tree gfc_trans_exit (gfc_code * code) { tree exit_label; exit_label = code->ext.which_construct->exit_label; gcc_assert (exit_label); TREE_USED (exit_label) = 1; return build1_v (GOTO_EXPR, exit_label); } /* Get the initializer expression for the code and expr of an allocate. When no initializer is needed return NULL. */ static gfc_expr * allocate_get_initializer (gfc_code * code, gfc_expr * expr) { if (!gfc_bt_struct (expr->ts.type) && expr->ts.type != BT_CLASS) return NULL; /* An explicit type was given in allocate ( T:: object). */ if (code->ext.alloc.ts.type == BT_DERIVED && (code->ext.alloc.ts.u.derived->attr.alloc_comp || gfc_has_default_initializer (code->ext.alloc.ts.u.derived))) return gfc_default_initializer (&code->ext.alloc.ts); if (gfc_bt_struct (expr->ts.type) && (expr->ts.u.derived->attr.alloc_comp || gfc_has_default_initializer (expr->ts.u.derived))) return gfc_default_initializer (&expr->ts); if (expr->ts.type == BT_CLASS && (CLASS_DATA (expr)->ts.u.derived->attr.alloc_comp || gfc_has_default_initializer (CLASS_DATA (expr)->ts.u.derived))) return gfc_default_initializer (&CLASS_DATA (expr)->ts); return NULL; } /* Translate the ALLOCATE statement. */ tree gfc_trans_allocate (gfc_code * code) { gfc_alloc *al; gfc_expr *expr, *e3rhs = NULL, *init_expr; gfc_se se, se_sz; tree tmp; tree parm; tree stat; tree errmsg; tree errlen; tree label_errmsg; tree label_finish; tree memsz; tree al_vptr, al_len; /* If an expr3 is present, then store the tree for accessing its _vptr, and _len components in the variables, respectively. The element size, i.e. _vptr%size, is stored in expr3_esize. Any of the trees may be the NULL_TREE indicating that this is not available for expr3's type. */ tree expr3, expr3_vptr, expr3_len, expr3_esize; /* Classify what expr3 stores. */ enum { E3_UNSET = 0, E3_SOURCE, E3_MOLD, E3_DESC } e3_is; stmtblock_t block; stmtblock_t post; stmtblock_t final_block; tree nelems; bool upoly_expr, tmp_expr3_len_flag = false, al_len_needs_set, is_coarray; bool needs_caf_sync, caf_refs_comp; bool e3_has_nodescriptor = false; gfc_symtree *newsym = NULL; symbol_attribute caf_attr; gfc_actual_arglist *param_list; if (!code->ext.alloc.list) return NULL_TREE; stat = tmp = memsz = al_vptr = al_len = NULL_TREE; expr3 = expr3_vptr = expr3_len = expr3_esize = NULL_TREE; label_errmsg = label_finish = errmsg = errlen = NULL_TREE; e3_is = E3_UNSET; is_coarray = needs_caf_sync = false; gfc_init_block (&block); gfc_init_block (&post); gfc_init_block (&final_block); /* STAT= (and maybe ERRMSG=) is present. */ if (code->expr1) { /* STAT=. */ tree gfc_int4_type_node = gfc_get_int_type (4); stat = gfc_create_var (gfc_int4_type_node, "stat"); /* ERRMSG= only makes sense with STAT=. */ if (code->expr2) { gfc_init_se (&se, NULL); se.want_pointer = 1; gfc_conv_expr_lhs (&se, code->expr2); errmsg = se.expr; errlen = se.string_length; } else { errmsg = null_pointer_node; errlen = build_int_cst (gfc_charlen_type_node, 0); } /* GOTO destinations. */ label_errmsg = gfc_build_label_decl (NULL_TREE); label_finish = gfc_build_label_decl (NULL_TREE); TREE_USED (label_finish) = 0; } /* When an expr3 is present evaluate it only once. The standards prevent a dependency of expr3 on the objects in the allocate list. An expr3 can be pre-evaluated in all cases. One just has to make sure, to use the correct way, i.e., to get the descriptor or to get a reference expression. */ if (code->expr3) { bool vtab_needed = false, temp_var_needed = false, temp_obj_created = false; is_coarray = gfc_is_coarray (code->expr3); if (code->expr3->expr_type == EXPR_FUNCTION && !code->expr3->mold && (gfc_is_class_array_function (code->expr3) || gfc_is_alloc_class_scalar_function (code->expr3))) code->expr3->must_finalize = 1; /* Figure whether we need the vtab from expr3. */ for (al = code->ext.alloc.list; !vtab_needed && al != NULL; al = al->next) vtab_needed = (al->expr->ts.type == BT_CLASS); gfc_init_se (&se, NULL); /* When expr3 is a variable, i.e., a very simple expression, then convert it once here. */ if (code->expr3->expr_type == EXPR_VARIABLE || code->expr3->expr_type == EXPR_ARRAY || code->expr3->expr_type == EXPR_CONSTANT) { if (!code->expr3->mold || code->expr3->ts.type == BT_CHARACTER || vtab_needed || code->ext.alloc.arr_spec_from_expr3) { /* Convert expr3 to a tree. For all "simple" expression just get the descriptor or the reference, respectively, depending on the rank of the expr. */ if (code->ext.alloc.arr_spec_from_expr3 || code->expr3->rank != 0) gfc_conv_expr_descriptor (&se, code->expr3); else { gfc_conv_expr_reference (&se, code->expr3); /* gfc_conv_expr_reference wraps POINTER_PLUS_EXPR in a NOP_EXPR, which prevents gfortran from getting the vptr from the source=-expression. Remove the NOP_EXPR and go with the POINTER_PLUS_EXPR in this case. */ if (code->expr3->ts.type == BT_CLASS && TREE_CODE (se.expr) == NOP_EXPR && (TREE_CODE (TREE_OPERAND (se.expr, 0)) == POINTER_PLUS_EXPR || is_coarray)) se.expr = TREE_OPERAND (se.expr, 0); } /* Create a temp variable only for component refs to prevent having to go through the full deref-chain each time and to simplfy computation of array properties. */ temp_var_needed = TREE_CODE (se.expr) == COMPONENT_REF; } } else { /* In all other cases evaluate the expr3. */ symbol_attribute attr; /* Get the descriptor for all arrays, that are not allocatable or pointer, because the latter are descriptors already. The exception are function calls returning a class object: The descriptor is stored in their results _data component, which is easier to access, when first a temporary variable for the result is created and the descriptor retrieved from there. */ attr = gfc_expr_attr (code->expr3); if (code->expr3->rank != 0 && ((!attr.allocatable && !attr.pointer) || (code->expr3->expr_type == EXPR_FUNCTION && (code->expr3->ts.type != BT_CLASS || (code->expr3->value.function.isym && code->expr3->value.function.isym ->transformational))))) gfc_conv_expr_descriptor (&se, code->expr3); else gfc_conv_expr_reference (&se, code->expr3); if (code->expr3->ts.type == BT_CLASS) gfc_conv_class_to_class (&se, code->expr3, code->expr3->ts, false, true, false, false); temp_obj_created = temp_var_needed = !VAR_P (se.expr); } gfc_add_block_to_block (&block, &se.pre); if (code->expr3->must_finalize) gfc_add_block_to_block (&final_block, &se.post); else gfc_add_block_to_block (&post, &se.post); /* Special case when string in expr3 is zero. */ if (code->expr3->ts.type == BT_CHARACTER && integer_zerop (se.string_length)) { gfc_init_se (&se, NULL); temp_var_needed = false; expr3_len = build_zero_cst (gfc_charlen_type_node); e3_is = E3_MOLD; } /* Prevent aliasing, i.e., se.expr may be already a variable declaration. */ else if (se.expr != NULL_TREE && temp_var_needed) { tree var, desc; tmp = GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (se.expr)) || is_coarray ? se.expr : build_fold_indirect_ref_loc (input_location, se.expr); /* Get the array descriptor and prepare it to be assigned to the temporary variable var. For classes the array descriptor is in the _data component and the object goes into the GFC_DECL_SAVED_DESCRIPTOR. */ if (code->expr3->ts.type == BT_CLASS && code->expr3->rank != 0) { /* When an array_ref was in expr3, then the descriptor is the first operand. */ if (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (tmp)) || is_coarray) { desc = TREE_OPERAND (tmp, 0); } else { desc = tmp; tmp = gfc_class_data_get (tmp); } if (code->ext.alloc.arr_spec_from_expr3) e3_is = E3_DESC; } else desc = !is_coarray ? se.expr : TREE_OPERAND (TREE_OPERAND (se.expr, 0), 0); /* We need a regular (non-UID) symbol here, therefore give a prefix. */ var = gfc_create_var (TREE_TYPE (tmp), "source"); if (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (tmp)) || is_coarray) { gfc_allocate_lang_decl (var); GFC_DECL_SAVED_DESCRIPTOR (var) = desc; } gfc_add_modify_loc (input_location, &block, var, tmp); expr3 = var; if (se.string_length) /* Evaluate it assuming that it also is complicated like expr3. */ expr3_len = gfc_evaluate_now (se.string_length, &block); } else { expr3 = se.expr; expr3_len = se.string_length; } /* Deallocate any allocatable components in expressions that use a temporary object, i.e. are not a simple alias of to an EXPR_VARIABLE. E.g. temporaries of a function call need freeing of their components here. */ if ((code->expr3->ts.type == BT_DERIVED || code->expr3->ts.type == BT_CLASS) && (code->expr3->expr_type != EXPR_VARIABLE || temp_obj_created) && code->expr3->ts.u.derived->attr.alloc_comp && !code->expr3->must_finalize) { tmp = gfc_deallocate_alloc_comp (code->expr3->ts.u.derived, expr3, code->expr3->rank); gfc_prepend_expr_to_block (&post, tmp); } /* Store what the expr3 is to be used for. */ if (e3_is == E3_UNSET) e3_is = expr3 != NULL_TREE ? (code->ext.alloc.arr_spec_from_expr3 ? E3_DESC : (code->expr3->mold ? E3_MOLD : E3_SOURCE)) : E3_UNSET; /* Figure how to get the _vtab entry. This also obtains the tree expression for accessing the _len component, because only unlimited polymorphic objects, which are a subcategory of class types, have a _len component. */ if (code->expr3->ts.type == BT_CLASS) { gfc_expr *rhs; tmp = expr3 != NULL_TREE && POINTER_TYPE_P (TREE_TYPE (expr3)) ? build_fold_indirect_ref (expr3): expr3; /* Polymorphic SOURCE: VPTR must be determined at run time. expr3 may be a temporary array declaration, therefore check for GFC_CLASS_TYPE_P before trying to get the _vptr component. */ if (tmp != NULL_TREE && (e3_is == E3_DESC || (GFC_CLASS_TYPE_P (TREE_TYPE (tmp)) && (VAR_P (tmp) || !code->expr3->ref)) || (VAR_P (tmp) && DECL_LANG_SPECIFIC (tmp)))) tmp = gfc_class_vptr_get (expr3); else { rhs = gfc_find_and_cut_at_last_class_ref (code->expr3); gfc_add_vptr_component (rhs); gfc_init_se (&se, NULL); se.want_pointer = 1; gfc_conv_expr (&se, rhs); tmp = se.expr; gfc_free_expr (rhs); } /* Set the element size. */ expr3_esize = gfc_vptr_size_get (tmp); if (vtab_needed) expr3_vptr = tmp; /* Initialize the ref to the _len component. */ if (expr3_len == NULL_TREE && UNLIMITED_POLY (code->expr3)) { /* Same like for retrieving the _vptr. */ if (expr3 != NULL_TREE && !code->expr3->ref) expr3_len = gfc_class_len_get (expr3); else { rhs = gfc_find_and_cut_at_last_class_ref (code->expr3); gfc_add_len_component (rhs); gfc_init_se (&se, NULL); gfc_conv_expr (&se, rhs); expr3_len = se.expr; gfc_free_expr (rhs); } } } else { /* When the object to allocate is polymorphic type, then it needs its vtab set correctly, so deduce the required _vtab and _len from the source expression. */ if (vtab_needed) { /* VPTR is fixed at compile time. */ gfc_symbol *vtab; vtab = gfc_find_vtab (&code->expr3->ts); gcc_assert (vtab); expr3_vptr = gfc_get_symbol_decl (vtab); expr3_vptr = gfc_build_addr_expr (NULL_TREE, expr3_vptr); } /* _len component needs to be set, when ts is a character array. */ if (expr3_len == NULL_TREE && code->expr3->ts.type == BT_CHARACTER) { if (code->expr3->ts.u.cl && code->expr3->ts.u.cl->length) { gfc_init_se (&se, NULL); gfc_conv_expr (&se, code->expr3->ts.u.cl->length); gfc_add_block_to_block (&block, &se.pre); expr3_len = gfc_evaluate_now (se.expr, &block); } gcc_assert (expr3_len); } /* For character arrays only the kind's size is needed, because the array mem_size is _len * (elem_size = kind_size). For all other get the element size in the normal way. */ if (code->expr3->ts.type == BT_CHARACTER) expr3_esize = TYPE_SIZE_UNIT ( gfc_get_char_type (code->expr3->ts.kind)); else expr3_esize = TYPE_SIZE_UNIT ( gfc_typenode_for_spec (&code->expr3->ts)); } gcc_assert (expr3_esize); expr3_esize = fold_convert (sizetype, expr3_esize); if (e3_is == E3_MOLD) /* The expr3 is no longer valid after this point. */ expr3 = NULL_TREE; } else if (code->ext.alloc.ts.type != BT_UNKNOWN) { /* Compute the explicit typespec given only once for all objects to allocate. */ if (code->ext.alloc.ts.type != BT_CHARACTER) expr3_esize = TYPE_SIZE_UNIT ( gfc_typenode_for_spec (&code->ext.alloc.ts)); else if (code->ext.alloc.ts.u.cl->length != NULL) { gfc_expr *sz; sz = gfc_copy_expr (code->ext.alloc.ts.u.cl->length); gfc_init_se (&se_sz, NULL); gfc_conv_expr (&se_sz, sz); gfc_free_expr (sz); tmp = gfc_get_char_type (code->ext.alloc.ts.kind); tmp = TYPE_SIZE_UNIT (tmp); tmp = fold_convert (TREE_TYPE (se_sz.expr), tmp); gfc_add_block_to_block (&block, &se_sz.pre); expr3_esize = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (se_sz.expr), tmp, se_sz.expr); expr3_esize = gfc_evaluate_now (expr3_esize, &block); } else expr3_esize = NULL_TREE; } /* The routine gfc_trans_assignment () already implements all techniques needed. Unfortunately we may have a temporary variable for the source= expression here. When that is the case convert this variable into a temporary gfc_expr of type EXPR_VARIABLE and used it as rhs for the assignment. The advantage is, that we get scalarizer support for free, don't have to take care about scalar to array treatment and will benefit of every enhancements gfc_trans_assignment () gets. No need to check whether e3_is is E3_UNSET, because that is done by expr3 != NULL_TREE. Exclude variables since the following block does not handle array sections. In any case, there is no harm in sending variables to gfc_trans_assignment because there is no evaluation of variables. */ if (code->expr3) { if (code->expr3->expr_type != EXPR_VARIABLE && e3_is != E3_MOLD && expr3 != NULL_TREE && DECL_P (expr3) && DECL_ARTIFICIAL (expr3)) { /* Build a temporary symtree and symbol. Do not add it to the current namespace to prevent accidently modifying a colliding symbol's as. */ newsym = XCNEW (gfc_symtree); /* The name of the symtree should be unique, because gfc_create_var () took care about generating the identifier. */ newsym->name = gfc_get_string ("%s", IDENTIFIER_POINTER (DECL_NAME (expr3))); newsym->n.sym = gfc_new_symbol (newsym->name, NULL); /* The backend_decl is known. It is expr3, which is inserted here. */ newsym->n.sym->backend_decl = expr3; e3rhs = gfc_get_expr (); e3rhs->rank = code->expr3->rank; e3rhs->symtree = newsym; /* Mark the symbol referenced or gfc_trans_assignment will bug. */ newsym->n.sym->attr.referenced = 1; e3rhs->expr_type = EXPR_VARIABLE; e3rhs->where = code->expr3->where; /* Set the symbols type, upto it was BT_UNKNOWN. */ if (IS_CLASS_ARRAY (code->expr3) && code->expr3->expr_type == EXPR_FUNCTION && code->expr3->value.function.isym && code->expr3->value.function.isym->transformational) { e3rhs->ts = CLASS_DATA (code->expr3)->ts; } else if (code->expr3->ts.type == BT_CLASS && !GFC_CLASS_TYPE_P (TREE_TYPE (expr3))) e3rhs->ts = CLASS_DATA (code->expr3)->ts; else e3rhs->ts = code->expr3->ts; newsym->n.sym->ts = e3rhs->ts; /* Check whether the expr3 is array valued. */ if (e3rhs->rank) { gfc_array_spec *arr; arr = gfc_get_array_spec (); arr->rank = e3rhs->rank; arr->type = AS_DEFERRED; /* Set the dimension and pointer attribute for arrays to be on the safe side. */ newsym->n.sym->attr.dimension = 1; newsym->n.sym->attr.pointer = 1; newsym->n.sym->as = arr; if (IS_CLASS_ARRAY (code->expr3) && code->expr3->expr_type == EXPR_FUNCTION && code->expr3->value.function.isym && code->expr3->value.function.isym->transformational) { gfc_array_spec *tarr; tarr = gfc_get_array_spec (); *tarr = *arr; e3rhs->ts.u.derived->as = tarr; } gfc_add_full_array_ref (e3rhs, arr); } else if (POINTER_TYPE_P (TREE_TYPE (expr3))) newsym->n.sym->attr.pointer = 1; /* The string length is known, too. Set it for char arrays. */ if (e3rhs->ts.type == BT_CHARACTER) newsym->n.sym->ts.u.cl->backend_decl = expr3_len; gfc_commit_symbol (newsym->n.sym); } else e3rhs = gfc_copy_expr (code->expr3); // We need to propagate the bounds of the expr3 for source=/mold=; // however, for nondescriptor arrays, we use internally a lower bound // of zero instead of one, which needs to be corrected for the allocate obj if (e3_is == E3_DESC) { symbol_attribute attr = gfc_expr_attr (code->expr3); if (code->expr3->expr_type == EXPR_ARRAY || (!attr.allocatable && !attr.pointer)) e3_has_nodescriptor = true; } } /* Loop over all objects to allocate. */ for (al = code->ext.alloc.list; al != NULL; al = al->next) { expr = gfc_copy_expr (al->expr); /* UNLIMITED_POLY () needs the _data component to be set, when expr is a unlimited polymorphic object. But the _data component has not been set yet, so check the derived type's attr for the unlimited polymorphic flag to be safe. */ upoly_expr = UNLIMITED_POLY (expr) || (expr->ts.type == BT_DERIVED && expr->ts.u.derived->attr.unlimited_polymorphic); gfc_init_se (&se, NULL); /* For class types prepare the expressions to ref the _vptr and the _len component. The latter for unlimited polymorphic types only. */ if (expr->ts.type == BT_CLASS) { gfc_expr *expr_ref_vptr, *expr_ref_len; gfc_add_data_component (expr); /* Prep the vptr handle. */ expr_ref_vptr = gfc_copy_expr (al->expr); gfc_add_vptr_component (expr_ref_vptr); se.want_pointer = 1; gfc_conv_expr (&se, expr_ref_vptr); al_vptr = se.expr; se.want_pointer = 0; gfc_free_expr (expr_ref_vptr); /* Allocated unlimited polymorphic objects always have a _len component. */ if (upoly_expr) { expr_ref_len = gfc_copy_expr (al->expr); gfc_add_len_component (expr_ref_len); gfc_conv_expr (&se, expr_ref_len); al_len = se.expr; gfc_free_expr (expr_ref_len); } else /* In a loop ensure that all loop variable dependent variables are initialized at the same spot in all execution paths. */ al_len = NULL_TREE; } else al_vptr = al_len = NULL_TREE; se.want_pointer = 1; se.descriptor_only = 1; gfc_conv_expr (&se, expr); if (expr->ts.type == BT_CHARACTER && expr->ts.deferred) /* se.string_length now stores the .string_length variable of expr needed to allocate character(len=:) arrays. */ al_len = se.string_length; al_len_needs_set = al_len != NULL_TREE; /* When allocating an array one cannot use much of the pre-evaluated expr3 expressions, because for most of them the scalarizer is needed which is not available in the pre-evaluation step. Therefore gfc_array_allocate () is responsible (and able) to handle the complete array allocation. Only the element size needs to be provided, which is done most of the time by the pre-evaluation step. */ nelems = NULL_TREE; if (expr3_len && (code->expr3->ts.type == BT_CHARACTER || code->expr3->ts.type == BT_CLASS)) { /* When al is an array, then the element size for each element in the array is needed, which is the product of the len and esize for char arrays. For unlimited polymorphics len can be zero, therefore take the maximum of len and one. */ tmp = fold_build2_loc (input_location, MAX_EXPR, TREE_TYPE (expr3_len), expr3_len, fold_convert (TREE_TYPE (expr3_len), integer_one_node)); tmp = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (expr3_esize), expr3_esize, fold_convert (TREE_TYPE (expr3_esize), tmp)); } else tmp = expr3_esize; if (!gfc_array_allocate (&se, expr, stat, errmsg, errlen, label_finish, tmp, &nelems, e3rhs ? e3rhs : code->expr3, e3_is == E3_DESC ? expr3 : NULL_TREE, e3_has_nodescriptor)) { /* A scalar or derived type. First compute the size to allocate. expr3_len is set when expr3 is an unlimited polymorphic object or a deferred length string. */ if (expr3_len != NULL_TREE) { tmp = fold_convert (TREE_TYPE (expr3_esize), expr3_len); tmp = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (expr3_esize), expr3_esize, tmp); if (code->expr3->ts.type != BT_CLASS) /* expr3 is a deferred length string, i.e., we are done. */ memsz = tmp; else { /* For unlimited polymorphic enties build (len > 0) ? element_size * len : element_size to compute the number of bytes to allocate. This allows the allocation of unlimited polymorphic objects from an expr3 that is also unlimited polymorphic and stores a _len dependent object, e.g., a string. */ memsz = fold_build2_loc (input_location, GT_EXPR, logical_type_node, expr3_len, build_zero_cst (TREE_TYPE (expr3_len))); memsz = fold_build3_loc (input_location, COND_EXPR, TREE_TYPE (expr3_esize), memsz, tmp, expr3_esize); } } else if (expr3_esize != NULL_TREE) /* Any other object in expr3 just needs element size in bytes. */ memsz = expr3_esize; else if ((expr->ts.type == BT_CHARACTER && expr->ts.deferred) || (upoly_expr && code->ext.alloc.ts.type == BT_CHARACTER)) { /* Allocating deferred length char arrays need the length to allocate in the alloc_type_spec. But also unlimited polymorphic objects may be allocated as char arrays. Both are handled here. */ gfc_init_se (&se_sz, NULL); gfc_conv_expr (&se_sz, code->ext.alloc.ts.u.cl->length); gfc_add_block_to_block (&se.pre, &se_sz.pre); se_sz.expr = gfc_evaluate_now (se_sz.expr, &se.pre); gfc_add_block_to_block (&se.pre, &se_sz.post); expr3_len = se_sz.expr; tmp_expr3_len_flag = true; tmp = TYPE_SIZE_UNIT ( gfc_get_char_type (code->ext.alloc.ts.kind)); memsz = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (tmp), fold_convert (TREE_TYPE (tmp), expr3_len), tmp); } else if (expr->ts.type == BT_CHARACTER) { /* Compute the number of bytes needed to allocate a fixed length char array. */ gcc_assert (se.string_length != NULL_TREE); tmp = TYPE_SIZE_UNIT (gfc_get_char_type (expr->ts.kind)); memsz = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (tmp), tmp, fold_convert (TREE_TYPE (tmp), se.string_length)); } else if (code->ext.alloc.ts.type != BT_UNKNOWN) /* Handle all types, where the alloc_type_spec is set. */ memsz = TYPE_SIZE_UNIT (gfc_typenode_for_spec (&code->ext.alloc.ts)); else /* Handle size computation of the type declared to alloc. */ memsz = TYPE_SIZE_UNIT (TREE_TYPE (TREE_TYPE (se.expr))); /* Store the caf-attributes for latter use. */ if (flag_coarray == GFC_FCOARRAY_LIB && (caf_attr = gfc_caf_attr (expr, true, &caf_refs_comp)) .codimension) { /* Scalar allocatable components in coarray'ed derived types make it here and are treated now. */ tree caf_decl, token; gfc_se caf_se; is_coarray = true; /* Set flag, to add synchronize after the allocate. */ needs_caf_sync = needs_caf_sync || caf_attr.coarray_comp || !caf_refs_comp; gfc_init_se (&caf_se, NULL); caf_decl = gfc_get_tree_for_caf_expr (expr); gfc_get_caf_token_offset (&caf_se, &token, NULL, caf_decl, NULL_TREE, NULL); gfc_add_block_to_block (&se.pre, &caf_se.pre); gfc_allocate_allocatable (&se.pre, se.expr, memsz, gfc_build_addr_expr (NULL_TREE, token), NULL_TREE, NULL_TREE, NULL_TREE, label_finish, expr, 1); } /* Allocate - for non-pointers with re-alloc checking. */ else if (gfc_expr_attr (expr).allocatable) gfc_allocate_allocatable (&se.pre, se.expr, memsz, NULL_TREE, stat, errmsg, errlen, label_finish, expr, 0); else gfc_allocate_using_malloc (&se.pre, se.expr, memsz, stat); } else { /* Allocating coarrays needs a sync after the allocate executed. Set the flag to add the sync after all objects are allocated. */ if (flag_coarray == GFC_FCOARRAY_LIB && (caf_attr = gfc_caf_attr (expr, true, &caf_refs_comp)) .codimension) { is_coarray = true; needs_caf_sync = needs_caf_sync || caf_attr.coarray_comp || !caf_refs_comp; } if (expr->ts.type == BT_CHARACTER && al_len != NULL_TREE && expr3_len != NULL_TREE) { /* Arrays need to have a _len set before the array descriptor is filled. */ gfc_add_modify (&block, al_len, fold_convert (TREE_TYPE (al_len), expr3_len)); /* Prevent setting the length twice. */ al_len_needs_set = false; } else if (expr->ts.type == BT_CHARACTER && al_len != NULL_TREE && code->ext.alloc.ts.u.cl->length) { /* Cover the cases where a string length is explicitly specified by a type spec for deferred length character arrays or unlimited polymorphic objects without a source= or mold= expression. */ gfc_init_se (&se_sz, NULL); gfc_conv_expr (&se_sz, code->ext.alloc.ts.u.cl->length); gfc_add_block_to_block (&block, &se_sz.pre); gfc_add_modify (&block, al_len, fold_convert (TREE_TYPE (al_len), se_sz.expr)); al_len_needs_set = false; } } gfc_add_block_to_block (&block, &se.pre); /* Error checking -- Note: ERRMSG only makes sense with STAT. */ if (code->expr1) { tmp = build1_v (GOTO_EXPR, label_errmsg); parm = fold_build2_loc (input_location, NE_EXPR, logical_type_node, stat, build_int_cst (TREE_TYPE (stat), 0)); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, gfc_unlikely (parm, PRED_FORTRAN_FAIL_ALLOC), tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } /* Set the vptr only when no source= is set. When source= is set, then the trans_assignment below will set the vptr. */ if (al_vptr != NULL_TREE && (!code->expr3 || code->expr3->mold)) { if (expr3_vptr != NULL_TREE) /* The vtab is already known, so just assign it. */ gfc_add_modify (&block, al_vptr, fold_convert (TREE_TYPE (al_vptr), expr3_vptr)); else { /* VPTR is fixed at compile time. */ gfc_symbol *vtab; gfc_typespec *ts; if (code->expr3) /* Although expr3 is pre-evaluated above, it may happen, that for arrays or in mold= cases the pre-evaluation was not successful. In these rare cases take the vtab from the typespec of expr3 here. */ ts = &code->expr3->ts; else if (code->ext.alloc.ts.type == BT_DERIVED || upoly_expr) /* The alloc_type_spec gives the type to allocate or the al is unlimited polymorphic, which enforces the use of an alloc_type_spec that is not necessarily a BT_DERIVED. */ ts = &code->ext.alloc.ts; else /* Prepare for setting the vtab as declared. */ ts = &expr->ts; vtab = gfc_find_vtab (ts); gcc_assert (vtab); tmp = gfc_build_addr_expr (NULL_TREE, gfc_get_symbol_decl (vtab)); gfc_add_modify (&block, al_vptr, fold_convert (TREE_TYPE (al_vptr), tmp)); } } /* Add assignment for string length. */ if (al_len != NULL_TREE && al_len_needs_set) { if (expr3_len != NULL_TREE) { gfc_add_modify (&block, al_len, fold_convert (TREE_TYPE (al_len), expr3_len)); /* When tmp_expr3_len_flag is set, then expr3_len is abused to carry the length information from the alloc_type. Clear it to prevent setting incorrect len information in future loop iterations. */ if (tmp_expr3_len_flag) /* No need to reset tmp_expr3_len_flag, because the presence of an expr3 cannot change within in the loop. */ expr3_len = NULL_TREE; } else if (code->ext.alloc.ts.type == BT_CHARACTER && code->ext.alloc.ts.u.cl->length) { /* Cover the cases where a string length is explicitly specified by a type spec for deferred length character arrays or unlimited polymorphic objects without a source= or mold= expression. */ if (expr3_esize == NULL_TREE || code->ext.alloc.ts.kind != 1) { gfc_init_se (&se_sz, NULL); gfc_conv_expr (&se_sz, code->ext.alloc.ts.u.cl->length); gfc_add_block_to_block (&block, &se_sz.pre); gfc_add_modify (&block, al_len, fold_convert (TREE_TYPE (al_len), se_sz.expr)); } else gfc_add_modify (&block, al_len, fold_convert (TREE_TYPE (al_len), expr3_esize)); } else /* No length information needed, because type to allocate has no length. Set _len to 0. */ gfc_add_modify (&block, al_len, fold_convert (TREE_TYPE (al_len), integer_zero_node)); } init_expr = NULL; if (code->expr3 && !code->expr3->mold && e3_is != E3_MOLD) { /* Initialization via SOURCE block (or static default initializer). Switch off automatic reallocation since we have just done the ALLOCATE. */ int realloc_lhs = flag_realloc_lhs; gfc_expr *init_expr = gfc_expr_to_initialize (expr); gfc_expr *rhs = e3rhs ? e3rhs : gfc_copy_expr (code->expr3); flag_realloc_lhs = 0; tmp = gfc_trans_assignment (init_expr, rhs, false, false, true, false); flag_realloc_lhs = realloc_lhs; /* Free the expression allocated for init_expr. */ gfc_free_expr (init_expr); if (rhs != e3rhs) gfc_free_expr (rhs); gfc_add_expr_to_block (&block, tmp); } /* Set KIND and LEN PDT components and allocate those that are parameterized. */ else if (expr->ts.type == BT_DERIVED && expr->ts.u.derived->attr.pdt_type) { if (code->expr3 && code->expr3->param_list) param_list = code->expr3->param_list; else if (expr->param_list) param_list = expr->param_list; else param_list = expr->symtree->n.sym->param_list; tmp = gfc_allocate_pdt_comp (expr->ts.u.derived, se.expr, expr->rank, param_list); gfc_add_expr_to_block (&block, tmp); } /* Ditto for CLASS expressions. */ else if (expr->ts.type == BT_CLASS && CLASS_DATA (expr)->ts.u.derived->attr.pdt_type) { if (code->expr3 && code->expr3->param_list) param_list = code->expr3->param_list; else if (expr->param_list) param_list = expr->param_list; else param_list = expr->symtree->n.sym->param_list; tmp = gfc_allocate_pdt_comp (CLASS_DATA (expr)->ts.u.derived, se.expr, expr->rank, param_list); gfc_add_expr_to_block (&block, tmp); } else if (code->expr3 && code->expr3->mold && code->expr3->ts.type == BT_CLASS) { /* Use class_init_assign to initialize expr. */ gfc_code *ini; ini = gfc_get_code (EXEC_INIT_ASSIGN); ini->expr1 = gfc_find_and_cut_at_last_class_ref (expr, true); tmp = gfc_trans_class_init_assign (ini); gfc_free_statements (ini); gfc_add_expr_to_block (&block, tmp); } else if ((init_expr = allocate_get_initializer (code, expr))) { /* Use class_init_assign to initialize expr. */ gfc_code *ini; int realloc_lhs = flag_realloc_lhs; ini = gfc_get_code (EXEC_INIT_ASSIGN); ini->expr1 = gfc_expr_to_initialize (expr); ini->expr2 = init_expr; flag_realloc_lhs = 0; tmp= gfc_trans_init_assign (ini); flag_realloc_lhs = realloc_lhs; gfc_free_statements (ini); /* Init_expr is freeed by above free_statements, just need to null it here. */ init_expr = NULL; gfc_add_expr_to_block (&block, tmp); } /* Nullify all pointers in derived type coarrays. This registers a token for them which allows their allocation. */ if (is_coarray) { gfc_symbol *type = NULL; symbol_attribute caf_attr; int rank = 0; if (code->ext.alloc.ts.type == BT_DERIVED && code->ext.alloc.ts.u.derived->attr.pointer_comp) { type = code->ext.alloc.ts.u.derived; rank = type->attr.dimension ? type->as->rank : 0; gfc_clear_attr (&caf_attr); } else if (expr->ts.type == BT_DERIVED && expr->ts.u.derived->attr.pointer_comp) { type = expr->ts.u.derived; rank = expr->rank; caf_attr = gfc_caf_attr (expr, true); } /* Initialize the tokens of pointer components in derived type coarrays. */ if (type) { tmp = (caf_attr.codimension && !caf_attr.dimension) ? gfc_conv_descriptor_data_get (se.expr) : se.expr; tmp = gfc_nullify_alloc_comp (type, tmp, rank, GFC_STRUCTURE_CAF_MODE_IN_COARRAY); gfc_add_expr_to_block (&block, tmp); } } gfc_free_expr (expr); } // for-loop if (e3rhs) { if (newsym) { gfc_free_symbol (newsym->n.sym); XDELETE (newsym); } gfc_free_expr (e3rhs); } /* STAT. */ if (code->expr1) { tmp = build1_v (LABEL_EXPR, label_errmsg); gfc_add_expr_to_block (&block, tmp); } /* ERRMSG - only useful if STAT is present. */ if (code->expr1 && code->expr2) { const char *msg = "Attempt to allocate an allocated object"; tree slen, dlen, errmsg_str; stmtblock_t errmsg_block; gfc_init_block (&errmsg_block); errmsg_str = gfc_create_var (pchar_type_node, "ERRMSG"); gfc_add_modify (&errmsg_block, errmsg_str, gfc_build_addr_expr (pchar_type_node, gfc_build_localized_cstring_const (msg))); slen = build_int_cst (gfc_charlen_type_node, strlen (msg)); dlen = gfc_get_expr_charlen (code->expr2); slen = fold_build2_loc (input_location, MIN_EXPR, TREE_TYPE (slen), dlen, slen); gfc_trans_string_copy (&errmsg_block, dlen, errmsg, code->expr2->ts.kind, slen, errmsg_str, gfc_default_character_kind); dlen = gfc_finish_block (&errmsg_block); tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, stat, build_int_cst (TREE_TYPE (stat), 0)); tmp = build3_v (COND_EXPR, tmp, dlen, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } /* STAT block. */ if (code->expr1) { if (TREE_USED (label_finish)) { tmp = build1_v (LABEL_EXPR, label_finish); gfc_add_expr_to_block (&block, tmp); } gfc_init_se (&se, NULL); gfc_conv_expr_lhs (&se, code->expr1); tmp = convert (TREE_TYPE (se.expr), stat); gfc_add_modify (&block, se.expr, tmp); } if (needs_caf_sync) { /* Add a sync all after the allocation has been executed. */ tree zero_size = build_zero_cst (size_type_node); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_all, 3, null_pointer_node, null_pointer_node, zero_size); gfc_add_expr_to_block (&post, tmp); } gfc_add_block_to_block (&block, &se.post); gfc_add_block_to_block (&block, &post); if (code->expr3 && code->expr3->must_finalize) gfc_add_block_to_block (&block, &final_block); return gfc_finish_block (&block); } /* Translate a DEALLOCATE statement. */ tree gfc_trans_deallocate (gfc_code *code) { gfc_se se; gfc_alloc *al; tree apstat, pstat, stat, errmsg, errlen, tmp; tree label_finish, label_errmsg; stmtblock_t block; pstat = apstat = stat = errmsg = errlen = tmp = NULL_TREE; label_finish = label_errmsg = NULL_TREE; gfc_start_block (&block); /* Count the number of failed deallocations. If deallocate() was called with STAT= , then set STAT to the count. If deallocate was called with ERRMSG, then set ERRMG to a string. */ if (code->expr1) { tree gfc_int4_type_node = gfc_get_int_type (4); stat = gfc_create_var (gfc_int4_type_node, "stat"); pstat = gfc_build_addr_expr (NULL_TREE, stat); /* GOTO destinations. */ label_errmsg = gfc_build_label_decl (NULL_TREE); label_finish = gfc_build_label_decl (NULL_TREE); TREE_USED (label_finish) = 0; } /* Set ERRMSG - only needed if STAT is available. */ if (code->expr1 && code->expr2) { gfc_init_se (&se, NULL); se.want_pointer = 1; gfc_conv_expr_lhs (&se, code->expr2); errmsg = se.expr; errlen = se.string_length; } for (al = code->ext.alloc.list; al != NULL; al = al->next) { gfc_expr *expr = gfc_copy_expr (al->expr); bool is_coarray = false, is_coarray_array = false; int caf_mode = 0; gcc_assert (expr->expr_type == EXPR_VARIABLE); if (expr->ts.type == BT_CLASS) gfc_add_data_component (expr); gfc_init_se (&se, NULL); gfc_start_block (&se.pre); se.want_pointer = 1; se.descriptor_only = 1; gfc_conv_expr (&se, expr); /* Deallocate PDT components that are parameterized. */ tmp = NULL; if (expr->ts.type == BT_DERIVED && expr->ts.u.derived->attr.pdt_type && expr->symtree->n.sym->param_list) tmp = gfc_deallocate_pdt_comp (expr->ts.u.derived, se.expr, expr->rank); else if (expr->ts.type == BT_CLASS && CLASS_DATA (expr)->ts.u.derived->attr.pdt_type && expr->symtree->n.sym->param_list) tmp = gfc_deallocate_pdt_comp (CLASS_DATA (expr)->ts.u.derived, se.expr, expr->rank); if (tmp) gfc_add_expr_to_block (&block, tmp); if (flag_coarray == GFC_FCOARRAY_LIB || flag_coarray == GFC_FCOARRAY_SINGLE) { bool comp_ref; symbol_attribute caf_attr = gfc_caf_attr (expr, false, &comp_ref); if (caf_attr.codimension) { is_coarray = true; is_coarray_array = caf_attr.dimension || !comp_ref || caf_attr.coarray_comp; if (flag_coarray == GFC_FCOARRAY_LIB) /* When the expression to deallocate is referencing a component, then only deallocate it, but do not deregister. */ caf_mode = GFC_STRUCTURE_CAF_MODE_IN_COARRAY | (comp_ref && !caf_attr.coarray_comp ? GFC_STRUCTURE_CAF_MODE_DEALLOC_ONLY : 0); } } if (expr->rank || is_coarray_array) { gfc_ref *ref; if (gfc_bt_struct (expr->ts.type) && expr->ts.u.derived->attr.alloc_comp && !gfc_is_finalizable (expr->ts.u.derived, NULL)) { gfc_ref *last = NULL; for (ref = expr->ref; ref; ref = ref->next) if (ref->type == REF_COMPONENT) last = ref; /* Do not deallocate the components of a derived type ultimate pointer component. */ if (!(last && last->u.c.component->attr.pointer) && !(!last && expr->symtree->n.sym->attr.pointer)) { if (is_coarray && expr->rank == 0 && (!last || !last->u.c.component->attr.dimension) && GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (se.expr))) { /* Add the ref to the data member only, when this is not a regular array or deallocate_alloc_comp will try to add another one. */ tmp = gfc_conv_descriptor_data_get (se.expr); } else tmp = se.expr; tmp = gfc_deallocate_alloc_comp (expr->ts.u.derived, tmp, expr->rank, caf_mode); gfc_add_expr_to_block (&se.pre, tmp); } } if (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (se.expr))) { gfc_coarray_deregtype caf_dtype; if (is_coarray) caf_dtype = gfc_caf_is_dealloc_only (caf_mode) ? GFC_CAF_COARRAY_DEALLOCATE_ONLY : GFC_CAF_COARRAY_DEREGISTER; else caf_dtype = GFC_CAF_COARRAY_NOCOARRAY; tmp = gfc_deallocate_with_status (se.expr, pstat, errmsg, errlen, label_finish, false, expr, caf_dtype); gfc_add_expr_to_block (&se.pre, tmp); } else if (TREE_CODE (se.expr) == COMPONENT_REF && TREE_CODE (TREE_TYPE (se.expr)) == ARRAY_TYPE && TREE_CODE (TREE_TYPE (TREE_TYPE (se.expr))) == RECORD_TYPE) { /* class.c(finalize_component) generates these, when a finalizable entity has a non-allocatable derived type array component, which has allocatable components. Obtain the derived type of the array and deallocate the allocatable components. */ for (ref = expr->ref; ref; ref = ref->next) { if (ref->u.c.component->attr.dimension && ref->u.c.component->ts.type == BT_DERIVED) break; } if (ref && ref->u.c.component->ts.u.derived->attr.alloc_comp && !gfc_is_finalizable (ref->u.c.component->ts.u.derived, NULL)) { tmp = gfc_deallocate_alloc_comp (ref->u.c.component->ts.u.derived, se.expr, expr->rank); gfc_add_expr_to_block (&se.pre, tmp); } } if (al->expr->ts.type == BT_CLASS) { gfc_reset_vptr (&se.pre, al->expr); if (UNLIMITED_POLY (al->expr) || (al->expr->ts.type == BT_DERIVED && al->expr->ts.u.derived->attr.unlimited_polymorphic)) /* Clear _len, too. */ gfc_reset_len (&se.pre, al->expr); } } else { tmp = gfc_deallocate_scalar_with_status (se.expr, pstat, label_finish, false, al->expr, al->expr->ts, is_coarray); gfc_add_expr_to_block (&se.pre, tmp); /* Set to zero after deallocation. */ tmp = fold_build2_loc (input_location, MODIFY_EXPR, void_type_node, se.expr, build_int_cst (TREE_TYPE (se.expr), 0)); gfc_add_expr_to_block (&se.pre, tmp); if (al->expr->ts.type == BT_CLASS) { gfc_reset_vptr (&se.pre, al->expr); if (UNLIMITED_POLY (al->expr) || (al->expr->ts.type == BT_DERIVED && al->expr->ts.u.derived->attr.unlimited_polymorphic)) /* Clear _len, too. */ gfc_reset_len (&se.pre, al->expr); } } if (code->expr1) { tree cond; cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, stat, build_int_cst (TREE_TYPE (stat), 0)); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, gfc_unlikely (cond, PRED_FORTRAN_FAIL_ALLOC), build1_v (GOTO_EXPR, label_errmsg), build_empty_stmt (input_location)); gfc_add_expr_to_block (&se.pre, tmp); } tmp = gfc_finish_block (&se.pre); gfc_add_expr_to_block (&block, tmp); gfc_free_expr (expr); } if (code->expr1) { tmp = build1_v (LABEL_EXPR, label_errmsg); gfc_add_expr_to_block (&block, tmp); } /* Set ERRMSG - only needed if STAT is available. */ if (code->expr1 && code->expr2) { const char *msg = "Attempt to deallocate an unallocated object"; stmtblock_t errmsg_block; tree errmsg_str, slen, dlen, cond; gfc_init_block (&errmsg_block); errmsg_str = gfc_create_var (pchar_type_node, "ERRMSG"); gfc_add_modify (&errmsg_block, errmsg_str, gfc_build_addr_expr (pchar_type_node, gfc_build_localized_cstring_const (msg))); slen = build_int_cst (gfc_charlen_type_node, strlen (msg)); dlen = gfc_get_expr_charlen (code->expr2); gfc_trans_string_copy (&errmsg_block, dlen, errmsg, code->expr2->ts.kind, slen, errmsg_str, gfc_default_character_kind); tmp = gfc_finish_block (&errmsg_block); cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, stat, build_int_cst (TREE_TYPE (stat), 0)); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, gfc_unlikely (cond, PRED_FORTRAN_FAIL_ALLOC), tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } if (code->expr1 && TREE_USED (label_finish)) { tmp = build1_v (LABEL_EXPR, label_finish); gfc_add_expr_to_block (&block, tmp); } /* Set STAT. */ if (code->expr1) { gfc_init_se (&se, NULL); gfc_conv_expr_lhs (&se, code->expr1); tmp = convert (TREE_TYPE (se.expr), stat); gfc_add_modify (&block, se.expr, tmp); } return gfc_finish_block (&block); } #include "gt-fortran-trans-stmt.h"