/* Array translation routines Copyright (C) 2002, 2003, 2004, 2005 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 2, 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 COPYING. If not, write to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* trans-array.c-- Various array related code, including scalarization, allocation, initialization and other support routines. */ /* How the scalarizer works. In gfortran, array expressions use the same core routines as scalar expressions. First, a Scalarization State (SS) chain is built. This is done by walking the expression tree, and building a linear list of the terms in the expression. As the tree is walked, scalar subexpressions are translated. The scalarization parameters are stored in a gfc_loopinfo structure. First the start and stride of each term is calculated by gfc_conv_ss_startstride. During this process the expressions for the array descriptors and data pointers are also translated. If the expression is an assignment, we must then resolve any dependencies. In fortran all the rhs values of an assignment must be evaluated before any assignments take place. This can require a temporary array to store the values. We also require a temporary when we are passing array expressions or vector subecripts as procedure parameters. Array sections are passed without copying to a temporary. These use the scalarizer to determine the shape of the section. The flag loop->array_parameter tells the scalarizer that the actual values and loop variables will not be required. The function gfc_conv_loop_setup generates the scalarization setup code. It determines the range of the scalarizing loop variables. If a temporary is required, this is created and initialized. Code for scalar expressions taken outside the loop is also generated at this time. Next the offset and scaling required to translate from loop variables to array indices for each term is calculated. A call to gfc_start_scalarized_body marks the start of the scalarized expression. This creates a scope and declares the loop variables. Before calling this gfc_make_ss_chain_used must be used to indicate which terms will be used inside this loop. The scalar gfc_conv_* functions are then used to build the main body of the scalarization loop. Scalarization loop variables and precalculated scalar values are automatically substituted. Note that gfc_advance_se_ss_chain must be used, rather than changing the se->ss directly. For assignment expressions requiring a temporary two sub loops are generated. The first stores the result of the expression in the temporary, the second copies it to the result. A call to gfc_trans_scalarized_loop_boundary marks the end of the main loop code and the start of the copying loop. The temporary may be less than full rank. Finally gfc_trans_scalarizing_loops is called to generate the implicit do loops. The loops are added to the pre chain of the loopinfo. The post chain may still contain cleanup code. After the loop code has been added into its parent scope gfc_cleanup_loop is called to free all the SS allocated by the scalarizer. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tree.h" #include "tree-gimple.h" #include "ggc.h" #include "toplev.h" #include "real.h" #include "flags.h" #include "gfortran.h" #include "trans.h" #include "trans-stmt.h" #include "trans-types.h" #include "trans-array.h" #include "trans-const.h" #include "dependency.h" static gfc_ss *gfc_walk_subexpr (gfc_ss *, gfc_expr *); /* The contents of this structure aren't actually used, just the address. */ static gfc_ss gfc_ss_terminator_var; gfc_ss * const gfc_ss_terminator = &gfc_ss_terminator_var; static tree gfc_array_dataptr_type (tree desc) { return (GFC_TYPE_ARRAY_DATAPTR_TYPE (TREE_TYPE (desc))); } /* Build expressions to access the members of an array descriptor. It's surprisingly easy to mess up here, so never access an array descriptor by "brute force", always use these functions. This also avoids problems if we change the format of an array descriptor. To understand these magic numbers, look at the comments before gfc_build_array_type() in trans-types.c. The code within these defines should be the only code which knows the format of an array descriptor. Any code just needing to read obtain the bounds of an array should use gfc_conv_array_* rather than the following functions as these will return know constant values, and work with arrays which do not have descriptors. Don't forget to #undef these! */ #define DATA_FIELD 0 #define OFFSET_FIELD 1 #define DTYPE_FIELD 2 #define DIMENSION_FIELD 3 #define STRIDE_SUBFIELD 0 #define LBOUND_SUBFIELD 1 #define UBOUND_SUBFIELD 2 /* This provides READ-ONLY access to the data field. The field itself doesn't have the proper type. */ tree gfc_conv_descriptor_data_get (tree desc) { tree field, type, t; type = TREE_TYPE (desc); gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); field = TYPE_FIELDS (type); gcc_assert (DATA_FIELD == 0); t = build3 (COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); t = fold_convert (GFC_TYPE_ARRAY_DATAPTR_TYPE (type), t); return t; } /* This provides WRITE access to the data field. */ void gfc_conv_descriptor_data_set (stmtblock_t *block, tree desc, tree value) { tree field, type, t; type = TREE_TYPE (desc); gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); field = TYPE_FIELDS (type); gcc_assert (DATA_FIELD == 0); t = build3 (COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); gfc_add_modify_expr (block, t, fold_convert (TREE_TYPE (field), value)); } /* This provides address access to the data field. This should only be used by array allocation, passing this on to the runtime. */ tree gfc_conv_descriptor_data_addr (tree desc) { tree field, type, t; type = TREE_TYPE (desc); gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); field = TYPE_FIELDS (type); gcc_assert (DATA_FIELD == 0); t = build3 (COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); return gfc_build_addr_expr (NULL, t); } tree gfc_conv_descriptor_offset (tree desc) { tree type; tree field; type = TREE_TYPE (desc); gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); field = gfc_advance_chain (TYPE_FIELDS (type), OFFSET_FIELD); gcc_assert (field != NULL_TREE && TREE_TYPE (field) == gfc_array_index_type); return build3 (COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); } tree gfc_conv_descriptor_dtype (tree desc) { tree field; tree type; type = TREE_TYPE (desc); gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); field = gfc_advance_chain (TYPE_FIELDS (type), DTYPE_FIELD); gcc_assert (field != NULL_TREE && TREE_TYPE (field) == gfc_array_index_type); return build3 (COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); } static tree gfc_conv_descriptor_dimension (tree desc, tree dim) { tree field; tree type; tree tmp; type = TREE_TYPE (desc); gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); field = gfc_advance_chain (TYPE_FIELDS (type), DIMENSION_FIELD); gcc_assert (field != NULL_TREE && TREE_CODE (TREE_TYPE (field)) == ARRAY_TYPE && TREE_CODE (TREE_TYPE (TREE_TYPE (field))) == RECORD_TYPE); tmp = build3 (COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); tmp = gfc_build_array_ref (tmp, dim); return tmp; } tree gfc_conv_descriptor_stride (tree desc, tree dim) { tree tmp; tree field; tmp = gfc_conv_descriptor_dimension (desc, dim); field = TYPE_FIELDS (TREE_TYPE (tmp)); field = gfc_advance_chain (field, STRIDE_SUBFIELD); gcc_assert (field != NULL_TREE && TREE_TYPE (field) == gfc_array_index_type); tmp = build3 (COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); return tmp; } tree gfc_conv_descriptor_lbound (tree desc, tree dim) { tree tmp; tree field; tmp = gfc_conv_descriptor_dimension (desc, dim); field = TYPE_FIELDS (TREE_TYPE (tmp)); field = gfc_advance_chain (field, LBOUND_SUBFIELD); gcc_assert (field != NULL_TREE && TREE_TYPE (field) == gfc_array_index_type); tmp = build3 (COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); return tmp; } tree gfc_conv_descriptor_ubound (tree desc, tree dim) { tree tmp; tree field; tmp = gfc_conv_descriptor_dimension (desc, dim); field = TYPE_FIELDS (TREE_TYPE (tmp)); field = gfc_advance_chain (field, UBOUND_SUBFIELD); gcc_assert (field != NULL_TREE && TREE_TYPE (field) == gfc_array_index_type); tmp = build3 (COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); return tmp; } /* Build an null array descriptor constructor. */ tree gfc_build_null_descriptor (tree type) { tree field; tree tmp; gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); gcc_assert (DATA_FIELD == 0); field = TYPE_FIELDS (type); /* Set a NULL data pointer. */ tmp = tree_cons (field, null_pointer_node, NULL_TREE); tmp = build1 (CONSTRUCTOR, type, tmp); TREE_CONSTANT (tmp) = 1; TREE_INVARIANT (tmp) = 1; /* All other fields are ignored. */ return tmp; } /* Cleanup those #defines. */ #undef DATA_FIELD #undef OFFSET_FIELD #undef DTYPE_FIELD #undef DIMENSION_FIELD #undef STRIDE_SUBFIELD #undef LBOUND_SUBFIELD #undef UBOUND_SUBFIELD /* Mark a SS chain as used. Flags specifies in which loops the SS is used. flags & 1 = Main loop body. flags & 2 = temp copy loop. */ void gfc_mark_ss_chain_used (gfc_ss * ss, unsigned flags) { for (; ss != gfc_ss_terminator; ss = ss->next) ss->useflags = flags; } static void gfc_free_ss (gfc_ss *); /* Free a gfc_ss chain. */ static void gfc_free_ss_chain (gfc_ss * ss) { gfc_ss *next; while (ss != gfc_ss_terminator) { gcc_assert (ss != NULL); next = ss->next; gfc_free_ss (ss); ss = next; } } /* Free a SS. */ static void gfc_free_ss (gfc_ss * ss) { int n; switch (ss->type) { case GFC_SS_SECTION: case GFC_SS_VECTOR: for (n = 0; n < GFC_MAX_DIMENSIONS; n++) { if (ss->data.info.subscript[n]) gfc_free_ss_chain (ss->data.info.subscript[n]); } break; default: break; } gfc_free (ss); } /* Free all the SS associated with a loop. */ void gfc_cleanup_loop (gfc_loopinfo * loop) { gfc_ss *ss; gfc_ss *next; ss = loop->ss; while (ss != gfc_ss_terminator) { gcc_assert (ss != NULL); next = ss->loop_chain; gfc_free_ss (ss); ss = next; } } /* Associate a SS chain with a loop. */ void gfc_add_ss_to_loop (gfc_loopinfo * loop, gfc_ss * head) { gfc_ss *ss; if (head == gfc_ss_terminator) return; ss = head; for (; ss && ss != gfc_ss_terminator; ss = ss->next) { if (ss->next == gfc_ss_terminator) ss->loop_chain = loop->ss; else ss->loop_chain = ss->next; } gcc_assert (ss == gfc_ss_terminator); loop->ss = head; } /* Generate an initializer for a static pointer or allocatable array. */ void gfc_trans_static_array_pointer (gfc_symbol * sym) { tree type; gcc_assert (TREE_STATIC (sym->backend_decl)); /* Just zero the data member. */ type = TREE_TYPE (sym->backend_decl); DECL_INITIAL (sym->backend_decl) = gfc_build_null_descriptor (type); } /* Generate code to allocate an array temporary, or create a variable to hold the data. If size is NULL zero the descriptor so that so that the callee will allocate the array. Also generates code to free the array afterwards. */ static void gfc_trans_allocate_array_storage (gfc_loopinfo * loop, gfc_ss_info * info, tree size, tree nelem) { tree tmp; tree args; tree desc; bool onstack; desc = info->descriptor; info->offset = gfc_index_zero_node; if (size == NULL_TREE) { /* A callee allocated array. */ gfc_conv_descriptor_data_set (&loop->pre, desc, null_pointer_node); onstack = FALSE; } else { /* Allocate the temporary. */ onstack = gfc_can_put_var_on_stack (size); if (onstack) { /* Make a temporary variable to hold the data. */ tmp = fold_build2 (MINUS_EXPR, TREE_TYPE (nelem), nelem, integer_one_node); tmp = build_range_type (gfc_array_index_type, gfc_index_zero_node, tmp); tmp = build_array_type (gfc_get_element_type (TREE_TYPE (desc)), tmp); tmp = gfc_create_var (tmp, "A"); tmp = gfc_build_addr_expr (NULL, tmp); gfc_conv_descriptor_data_set (&loop->pre, desc, tmp); } else { /* Allocate memory to hold the data. */ args = gfc_chainon_list (NULL_TREE, size); if (gfc_index_integer_kind == 4) tmp = gfor_fndecl_internal_malloc; else if (gfc_index_integer_kind == 8) tmp = gfor_fndecl_internal_malloc64; else gcc_unreachable (); tmp = gfc_build_function_call (tmp, args); tmp = gfc_evaluate_now (tmp, &loop->pre); gfc_conv_descriptor_data_set (&loop->pre, desc, tmp); } } info->data = gfc_conv_descriptor_data_get (desc); /* The offset is zero because we create temporaries with a zero lower bound. */ tmp = gfc_conv_descriptor_offset (desc); gfc_add_modify_expr (&loop->pre, tmp, gfc_index_zero_node); if (!onstack) { /* Free the temporary. */ tmp = gfc_conv_descriptor_data_get (desc); tmp = fold_convert (pvoid_type_node, tmp); tmp = gfc_chainon_list (NULL_TREE, tmp); tmp = gfc_build_function_call (gfor_fndecl_internal_free, tmp); gfc_add_expr_to_block (&loop->post, tmp); } } /* Generate code to allocate and initialize the descriptor for a temporary array. This is used for both temporaries needed by the scalarizer, and functions returning arrays. Adjusts the loop variables to be zero-based, and calculates the loop bounds for callee allocated arrays. Also fills in the descriptor, data and offset fields of info if known. Returns the size of the array, or NULL for a callee allocated array. */ tree gfc_trans_allocate_temp_array (gfc_loopinfo * loop, gfc_ss_info * info, tree eltype) { tree type; tree desc; tree tmp; tree size; tree nelem; int n; int dim; gcc_assert (info->dimen > 0); /* Set the lower bound to zero. */ for (dim = 0; dim < info->dimen; dim++) { n = loop->order[dim]; if (n < loop->temp_dim) gcc_assert (integer_zerop (loop->from[n])); else { /* Callee allocated arrays may not have a known bound yet. */ if (loop->to[n]) loop->to[n] = fold_build2 (MINUS_EXPR, gfc_array_index_type, loop->to[n], loop->from[n]); loop->from[n] = gfc_index_zero_node; } info->delta[dim] = gfc_index_zero_node; info->start[dim] = gfc_index_zero_node; info->stride[dim] = gfc_index_one_node; info->dim[dim] = dim; } /* Initialize the descriptor. */ type = gfc_get_array_type_bounds (eltype, info->dimen, loop->from, loop->to, 1); desc = gfc_create_var (type, "atmp"); GFC_DECL_PACKED_ARRAY (desc) = 1; info->descriptor = desc; size = gfc_index_one_node; /* Fill in the array dtype. */ tmp = gfc_conv_descriptor_dtype (desc); gfc_add_modify_expr (&loop->pre, tmp, gfc_get_dtype (TREE_TYPE (desc))); /* Fill in the bounds and stride. This is a packed array, so: size = 1; for (n = 0; n < rank; n++) { stride[n] = size delta = ubound[n] + 1 - lbound[n]; size = size * delta; } size = size * sizeof(element); */ for (n = 0; n < info->dimen; n++) { if (loop->to[n] == NULL_TREE) { /* For a callee allocated array express the loop bounds in terms of the descriptor fields. */ tmp = build2 (MINUS_EXPR, gfc_array_index_type, gfc_conv_descriptor_ubound (desc, gfc_rank_cst[n]), gfc_conv_descriptor_lbound (desc, gfc_rank_cst[n])); loop->to[n] = tmp; size = NULL_TREE; continue; } /* Store the stride and bound components in the descriptor. */ tmp = gfc_conv_descriptor_stride (desc, gfc_rank_cst[n]); gfc_add_modify_expr (&loop->pre, tmp, size); tmp = gfc_conv_descriptor_lbound (desc, gfc_rank_cst[n]); gfc_add_modify_expr (&loop->pre, tmp, gfc_index_zero_node); tmp = gfc_conv_descriptor_ubound (desc, gfc_rank_cst[n]); gfc_add_modify_expr (&loop->pre, tmp, loop->to[n]); tmp = fold_build2 (PLUS_EXPR, gfc_array_index_type, loop->to[n], gfc_index_one_node); size = fold_build2 (MULT_EXPR, gfc_array_index_type, size, tmp); size = gfc_evaluate_now (size, &loop->pre); } /* Get the size of the array. */ nelem = size; if (size) size = fold_build2 (MULT_EXPR, gfc_array_index_type, size, TYPE_SIZE_UNIT (gfc_get_element_type (type))); gfc_trans_allocate_array_storage (loop, info, size, nelem); if (info->dimen > loop->temp_dim) loop->temp_dim = info->dimen; return size; } /* Make sure offset is a variable. */ static void gfc_put_offset_into_var (stmtblock_t * pblock, tree * poffset, tree * offsetvar) { /* We should have already created the offset variable. We cannot create it here because we may be in an inner scope. */ gcc_assert (*offsetvar != NULL_TREE); gfc_add_modify_expr (pblock, *offsetvar, *poffset); *poffset = *offsetvar; TREE_USED (*offsetvar) = 1; } /* Assign an element of an array constructor. */ static void gfc_trans_array_ctor_element (stmtblock_t * pblock, tree pointer, tree offset, gfc_se * se, gfc_expr * expr) { tree tmp; tree args; gfc_conv_expr (se, expr); /* Store the value. */ tmp = gfc_build_indirect_ref (pointer); tmp = gfc_build_array_ref (tmp, offset); if (expr->ts.type == BT_CHARACTER) { gfc_conv_string_parameter (se); if (POINTER_TYPE_P (TREE_TYPE (tmp))) { /* The temporary is an array of pointers. */ se->expr = fold_convert (TREE_TYPE (tmp), se->expr); gfc_add_modify_expr (&se->pre, tmp, se->expr); } else { /* The temporary is an array of string values. */ tmp = gfc_build_addr_expr (pchar_type_node, tmp); /* We know the temporary and the value will be the same length, so can use memcpy. */ args = gfc_chainon_list (NULL_TREE, tmp); args = gfc_chainon_list (args, se->expr); args = gfc_chainon_list (args, se->string_length); tmp = built_in_decls[BUILT_IN_MEMCPY]; tmp = gfc_build_function_call (tmp, args); gfc_add_expr_to_block (&se->pre, tmp); } } else { /* TODO: Should the frontend already have done this conversion? */ se->expr = fold_convert (TREE_TYPE (tmp), se->expr); gfc_add_modify_expr (&se->pre, tmp, se->expr); } gfc_add_block_to_block (pblock, &se->pre); gfc_add_block_to_block (pblock, &se->post); } /* Add the contents of an array to the constructor. */ static void gfc_trans_array_constructor_subarray (stmtblock_t * pblock, tree type ATTRIBUTE_UNUSED, tree pointer, gfc_expr * expr, tree * poffset, tree * offsetvar) { gfc_se se; gfc_ss *ss; gfc_loopinfo loop; stmtblock_t body; tree tmp; /* We need this to be a variable so we can increment it. */ gfc_put_offset_into_var (pblock, poffset, offsetvar); gfc_init_se (&se, NULL); /* Walk the array expression. */ ss = gfc_walk_expr (expr); gcc_assert (ss != gfc_ss_terminator); /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); gfc_add_ss_to_loop (&loop, ss); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop); /* Make the loop body. */ gfc_mark_ss_chain_used (ss, 1); gfc_start_scalarized_body (&loop, &body); gfc_copy_loopinfo_to_se (&se, &loop); se.ss = ss; if (expr->ts.type == BT_CHARACTER) gfc_todo_error ("character arrays in constructors"); gfc_trans_array_ctor_element (&body, pointer, *poffset, &se, expr); gcc_assert (se.ss == gfc_ss_terminator); /* Increment the offset. */ tmp = build2 (PLUS_EXPR, gfc_array_index_type, *poffset, gfc_index_one_node); gfc_add_modify_expr (&body, *poffset, tmp); /* Finish the loop. */ gfc_trans_scalarizing_loops (&loop, &body); gfc_add_block_to_block (&loop.pre, &loop.post); tmp = gfc_finish_block (&loop.pre); gfc_add_expr_to_block (pblock, tmp); gfc_cleanup_loop (&loop); } /* Assign the values to the elements of an array constructor. */ static void gfc_trans_array_constructor_value (stmtblock_t * pblock, tree type, tree pointer, gfc_constructor * c, tree * poffset, tree * offsetvar) { tree tmp; stmtblock_t body; gfc_se se; for (; c; c = c->next) { /* If this is an iterator or an array, the offset must be a variable. */ if ((c->iterator || c->expr->rank > 0) && INTEGER_CST_P (*poffset)) gfc_put_offset_into_var (pblock, poffset, offsetvar); gfc_start_block (&body); if (c->expr->expr_type == EXPR_ARRAY) { /* Array constructors can be nested. */ gfc_trans_array_constructor_value (&body, type, pointer, c->expr->value.constructor, poffset, offsetvar); } else if (c->expr->rank > 0) { gfc_trans_array_constructor_subarray (&body, type, pointer, c->expr, poffset, offsetvar); } else { /* This code really upsets the gimplifier so don't bother for now. */ gfc_constructor *p; HOST_WIDE_INT n; HOST_WIDE_INT size; p = c; n = 0; while (p && !(p->iterator || p->expr->expr_type != EXPR_CONSTANT)) { p = p->next; n++; } if (n < 4) { /* Scalar values. */ gfc_init_se (&se, NULL); gfc_trans_array_ctor_element (&body, pointer, *poffset, &se, c->expr); *poffset = fold_build2 (PLUS_EXPR, gfc_array_index_type, *poffset, gfc_index_one_node); } else { /* Collect multiple scalar constants into a constructor. */ tree list; tree init; tree bound; tree tmptype; p = c; list = NULL_TREE; /* Count the number of consecutive scalar constants. */ while (p && !(p->iterator || p->expr->expr_type != EXPR_CONSTANT)) { gfc_init_se (&se, NULL); gfc_conv_constant (&se, p->expr); if (p->expr->ts.type == BT_CHARACTER && POINTER_TYPE_P (TREE_TYPE (TREE_TYPE (TREE_TYPE (pointer))))) { /* For constant character array constructors we build an array of pointers. */ se.expr = gfc_build_addr_expr (pchar_type_node, se.expr); } list = tree_cons (NULL_TREE, se.expr, list); c = p; p = p->next; } bound = build_int_cst (NULL_TREE, n - 1); /* Create an array type to hold them. */ tmptype = build_range_type (gfc_array_index_type, gfc_index_zero_node, bound); tmptype = build_array_type (type, tmptype); init = build1 (CONSTRUCTOR, tmptype, nreverse (list)); TREE_CONSTANT (init) = 1; TREE_INVARIANT (init) = 1; TREE_STATIC (init) = 1; /* Create a static variable to hold the data. */ tmp = gfc_create_var (tmptype, "data"); TREE_STATIC (tmp) = 1; TREE_CONSTANT (tmp) = 1; TREE_INVARIANT (tmp) = 1; DECL_INITIAL (tmp) = init; init = tmp; /* Use BUILTIN_MEMCPY to assign the values. */ tmp = gfc_build_indirect_ref (pointer); tmp = gfc_build_array_ref (tmp, *poffset); tmp = gfc_build_addr_expr (NULL, tmp); init = gfc_build_addr_expr (NULL, init); size = TREE_INT_CST_LOW (TYPE_SIZE_UNIT (type)); bound = build_int_cst (NULL_TREE, n * size); tmp = gfc_chainon_list (NULL_TREE, tmp); tmp = gfc_chainon_list (tmp, init); tmp = gfc_chainon_list (tmp, bound); tmp = gfc_build_function_call (built_in_decls[BUILT_IN_MEMCPY], tmp); gfc_add_expr_to_block (&body, tmp); *poffset = fold_build2 (PLUS_EXPR, gfc_array_index_type, *poffset, bound); } if (!INTEGER_CST_P (*poffset)) { gfc_add_modify_expr (&body, *offsetvar, *poffset); *poffset = *offsetvar; } } /* The frontend should already have done any expansions possible at compile-time. */ if (!c->iterator) { /* Pass the code as is. */ tmp = gfc_finish_block (&body); gfc_add_expr_to_block (pblock, tmp); } else { /* Build the implied do-loop. */ tree cond; tree end; tree step; tree loopvar; tree exit_label; tree loopbody; loopbody = gfc_finish_block (&body); gfc_init_se (&se, NULL); gfc_conv_expr (&se, c->iterator->var); gfc_add_block_to_block (pblock, &se.pre); loopvar = se.expr; /* Initialize the loop. */ gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, c->iterator->start); gfc_add_block_to_block (pblock, &se.pre); gfc_add_modify_expr (pblock, loopvar, se.expr); gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, c->iterator->end); gfc_add_block_to_block (pblock, &se.pre); end = gfc_evaluate_now (se.expr, pblock); gfc_init_se (&se, NULL); gfc_conv_expr_val (&se, c->iterator->step); gfc_add_block_to_block (pblock, &se.pre); step = gfc_evaluate_now (se.expr, pblock); /* Generate the loop body. */ exit_label = gfc_build_label_decl (NULL_TREE); gfc_start_block (&body); /* Generate the exit condition. Depending on the sign of the step variable we have to generate the correct comparison. */ tmp = fold_build2 (GT_EXPR, boolean_type_node, step, build_int_cst (TREE_TYPE (step), 0)); cond = fold_build3 (COND_EXPR, boolean_type_node, tmp, build2 (GT_EXPR, boolean_type_node, loopvar, end), build2 (LT_EXPR, boolean_type_node, loopvar, end)); tmp = build1_v (GOTO_EXPR, exit_label); TREE_USED (exit_label) = 1; tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt ()); gfc_add_expr_to_block (&body, tmp); /* The main loop body. */ gfc_add_expr_to_block (&body, loopbody); /* Increase loop variable by step. */ tmp = build2 (PLUS_EXPR, TREE_TYPE (loopvar), loopvar, step); gfc_add_modify_expr (&body, loopvar, tmp); /* Finish the loop. */ tmp = gfc_finish_block (&body); tmp = build1_v (LOOP_EXPR, 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); } } } /* Get the size of an expression. Returns -1 if the size isn't constant. Implied do loops with non-constant bounds are tricky because we must only evaluate the bounds once. */ static void gfc_get_array_cons_size (mpz_t * size, gfc_constructor * c) { gfc_iterator *i; mpz_t val; mpz_t len; mpz_set_ui (*size, 0); mpz_init (len); mpz_init (val); for (; c; c = c->next) { if (c->expr->expr_type == EXPR_ARRAY) { /* A nested array constructor. */ gfc_get_array_cons_size (&len, c->expr->value.constructor); if (mpz_sgn (len) < 0) { mpz_set (*size, len); mpz_clear (len); mpz_clear (val); return; } } else { if (c->expr->rank > 0) { mpz_set_si (*size, -1); mpz_clear (len); mpz_clear (val); return; } mpz_set_ui (len, 1); } if (c->iterator) { i = c->iterator; if (i->start->expr_type != EXPR_CONSTANT || i->end->expr_type != EXPR_CONSTANT || i->step->expr_type != EXPR_CONSTANT) { mpz_set_si (*size, -1); mpz_clear (len); mpz_clear (val); return; } mpz_add (val, i->end->value.integer, i->start->value.integer); mpz_tdiv_q (val, val, i->step->value.integer); mpz_add_ui (val, val, 1); mpz_mul (len, len, val); } mpz_add (*size, *size, len); } mpz_clear (len); mpz_clear (val); } /* Figure out the string length of a variable reference expression. Used by get_array_ctor_strlen. */ static void get_array_ctor_var_strlen (gfc_expr * expr, tree * len) { gfc_ref *ref; gfc_typespec *ts; /* Don't bother if we already know the length is a constant. */ if (*len && INTEGER_CST_P (*len)) return; ts = &expr->symtree->n.sym->ts; for (ref = expr->ref; ref; ref = ref->next) { switch (ref->type) { case REF_ARRAY: /* Array references don't change the string length. */ break; case COMPONENT_REF: /* Use the length of the component. */ ts = &ref->u.c.component->ts; break; default: /* TODO: Substrings are tricky because we can't evaluate the expression more than once. For now we just give up, and hope we can figure it out elsewhere. */ return; } } *len = ts->cl->backend_decl; } /* Figure out the string length of a character array constructor. Returns TRUE if all elements are character constants. */ static bool get_array_ctor_strlen (gfc_constructor * c, tree * len) { bool is_const; is_const = TRUE; for (; c; c = c->next) { switch (c->expr->expr_type) { case EXPR_CONSTANT: if (!(*len && INTEGER_CST_P (*len))) *len = build_int_cstu (gfc_charlen_type_node, c->expr->value.character.length); break; case EXPR_ARRAY: if (!get_array_ctor_strlen (c->expr->value.constructor, len)) is_const = FALSE; break; case EXPR_VARIABLE: is_const = false; get_array_ctor_var_strlen (c->expr, len); break; default: is_const = FALSE; /* TODO: For now we just ignore anything we don't know how to handle, and hope we can figure it out a different way. */ break; } } return is_const; } /* Array constructors are handled by constructing a temporary, then using that within the scalarization loop. This is not optimal, but seems by far the simplest method. */ static void gfc_trans_array_constructor (gfc_loopinfo * loop, gfc_ss * ss) { tree offset; tree offsetvar; tree desc; tree size; tree type; bool const_string; ss->data.info.dimen = loop->dimen; if (ss->expr->ts.type == BT_CHARACTER) { const_string = get_array_ctor_strlen (ss->expr->value.constructor, &ss->string_length); if (!ss->string_length) gfc_todo_error ("complex character array constructors"); type = gfc_get_character_type_len (ss->expr->ts.kind, ss->string_length); if (const_string) type = build_pointer_type (type); } else { const_string = TRUE; type = gfc_typenode_for_spec (&ss->expr->ts); } size = gfc_trans_allocate_temp_array (loop, &ss->data.info, type); desc = ss->data.info.descriptor; offset = gfc_index_zero_node; offsetvar = gfc_create_var_np (gfc_array_index_type, "offset"); TREE_USED (offsetvar) = 0; gfc_trans_array_constructor_value (&loop->pre, type, ss->data.info.data, ss->expr->value.constructor, &offset, &offsetvar); if (TREE_USED (offsetvar)) pushdecl (offsetvar); else gcc_assert (INTEGER_CST_P (offset)); #if 0 /* Disable bound checking for now because it's probably broken. */ if (flag_bounds_check) { gcc_unreachable (); } #endif } /* Add the pre and post chains for all the scalar expressions in a SS chain to loop. This is called after the loop parameters have been calculated, but before the actual scalarizing loops. */ static void gfc_add_loop_ss_code (gfc_loopinfo * loop, gfc_ss * ss, bool subscript) { gfc_se se; int n; /* TODO: This can generate bad code if there are ordering dependencies. eg. a callee allocated function and an unknown size constructor. */ gcc_assert (ss != NULL); for (; ss != gfc_ss_terminator; ss = ss->loop_chain) { gcc_assert (ss); switch (ss->type) { case GFC_SS_SCALAR: /* Scalar expression. Evaluate this now. This includes elemental dimension indices, but not array section bounds. */ gfc_init_se (&se, NULL); gfc_conv_expr (&se, ss->expr); gfc_add_block_to_block (&loop->pre, &se.pre); if (ss->expr->ts.type != BT_CHARACTER) { /* Move the evaluation of scalar expressions outside the scalarization loop. */ if (subscript) se.expr = convert(gfc_array_index_type, se.expr); se.expr = gfc_evaluate_now (se.expr, &loop->pre); gfc_add_block_to_block (&loop->pre, &se.post); } else gfc_add_block_to_block (&loop->post, &se.post); ss->data.scalar.expr = se.expr; ss->string_length = se.string_length; break; case GFC_SS_REFERENCE: /* Scalar reference. Evaluate this now. */ gfc_init_se (&se, NULL); gfc_conv_expr_reference (&se, ss->expr); gfc_add_block_to_block (&loop->pre, &se.pre); gfc_add_block_to_block (&loop->post, &se.post); ss->data.scalar.expr = gfc_evaluate_now (se.expr, &loop->pre); ss->string_length = se.string_length; break; case GFC_SS_SECTION: case GFC_SS_VECTOR: /* Scalarized expression. Evaluate any scalar subscripts. */ for (n = 0; n < GFC_MAX_DIMENSIONS; n++) { /* Add the expressions for scalar subscripts. */ if (ss->data.info.subscript[n]) gfc_add_loop_ss_code (loop, ss->data.info.subscript[n], true); } break; case GFC_SS_INTRINSIC: gfc_add_intrinsic_ss_code (loop, ss); break; case GFC_SS_FUNCTION: /* Array function return value. We call the function and save its result in a temporary for use inside the loop. */ gfc_init_se (&se, NULL); se.loop = loop; se.ss = ss; gfc_conv_expr (&se, ss->expr); gfc_add_block_to_block (&loop->pre, &se.pre); gfc_add_block_to_block (&loop->post, &se.post); break; case GFC_SS_CONSTRUCTOR: gfc_trans_array_constructor (loop, ss); break; case GFC_SS_TEMP: case GFC_SS_COMPONENT: /* Do nothing. These are handled elsewhere. */ break; default: gcc_unreachable (); } } } /* Translate expressions for the descriptor and data pointer of a SS. */ /*GCC ARRAYS*/ static void gfc_conv_ss_descriptor (stmtblock_t * block, gfc_ss * ss, int base) { gfc_se se; tree tmp; /* Get the descriptor for the array to be scalarized. */ gcc_assert (ss->expr->expr_type == EXPR_VARIABLE); gfc_init_se (&se, NULL); se.descriptor_only = 1; gfc_conv_expr_lhs (&se, ss->expr); gfc_add_block_to_block (block, &se.pre); ss->data.info.descriptor = se.expr; ss->string_length = se.string_length; if (base) { /* Also the data pointer. */ tmp = gfc_conv_array_data (se.expr); /* If this is a variable or address of a variable we use it directly. Otherwise we must evaluate it now to avoid breaking dependency analysis by pulling the expressions for elemental array indices inside the loop. */ if (!(DECL_P (tmp) || (TREE_CODE (tmp) == ADDR_EXPR && DECL_P (TREE_OPERAND (tmp, 0))))) tmp = gfc_evaluate_now (tmp, block); ss->data.info.data = tmp; tmp = gfc_conv_array_offset (se.expr); ss->data.info.offset = gfc_evaluate_now (tmp, block); } } /* Initialize a gfc_loopinfo structure. */ void gfc_init_loopinfo (gfc_loopinfo * loop) { int n; memset (loop, 0, sizeof (gfc_loopinfo)); gfc_init_block (&loop->pre); gfc_init_block (&loop->post); /* Initially scalarize in order. */ for (n = 0; n < GFC_MAX_DIMENSIONS; n++) loop->order[n] = n; loop->ss = gfc_ss_terminator; } /* Copies the loop variable info to a gfc_se structure. Does not copy the SS chain. */ void gfc_copy_loopinfo_to_se (gfc_se * se, gfc_loopinfo * loop) { se->loop = loop; } /* Return an expression for the data pointer of an array. */ tree gfc_conv_array_data (tree descriptor) { tree type; type = TREE_TYPE (descriptor); if (GFC_ARRAY_TYPE_P (type)) { if (TREE_CODE (type) == POINTER_TYPE) return descriptor; else { /* Descriptorless arrays. */ return gfc_build_addr_expr (NULL, descriptor); } } else return gfc_conv_descriptor_data_get (descriptor); } /* Return an expression for the base offset of an array. */ tree gfc_conv_array_offset (tree descriptor) { tree type; type = TREE_TYPE (descriptor); if (GFC_ARRAY_TYPE_P (type)) return GFC_TYPE_ARRAY_OFFSET (type); else return gfc_conv_descriptor_offset (descriptor); } /* Get an expression for the array stride. */ tree gfc_conv_array_stride (tree descriptor, int dim) { tree tmp; tree type; type = TREE_TYPE (descriptor); /* For descriptorless arrays use the array size. */ tmp = GFC_TYPE_ARRAY_STRIDE (type, dim); if (tmp != NULL_TREE) return tmp; tmp = gfc_conv_descriptor_stride (descriptor, gfc_rank_cst[dim]); return tmp; } /* Like gfc_conv_array_stride, but for the lower bound. */ tree gfc_conv_array_lbound (tree descriptor, int dim) { tree tmp; tree type; type = TREE_TYPE (descriptor); tmp = GFC_TYPE_ARRAY_LBOUND (type, dim); if (tmp != NULL_TREE) return tmp; tmp = gfc_conv_descriptor_lbound (descriptor, gfc_rank_cst[dim]); return tmp; } /* Like gfc_conv_array_stride, but for the upper bound. */ tree gfc_conv_array_ubound (tree descriptor, int dim) { tree tmp; tree type; type = TREE_TYPE (descriptor); tmp = GFC_TYPE_ARRAY_UBOUND (type, dim); if (tmp != NULL_TREE) return tmp; /* This should only ever happen when passing an assumed shape array as an actual parameter. The value will never be used. */ if (GFC_ARRAY_TYPE_P (TREE_TYPE (descriptor))) return gfc_index_zero_node; tmp = gfc_conv_descriptor_ubound (descriptor, gfc_rank_cst[dim]); return tmp; } /* Translate an array reference. The descriptor should be in se->expr. Do not use this function, it wil be removed soon. */ /*GCC ARRAYS*/ static void gfc_conv_array_index_ref (gfc_se * se, tree pointer, tree * indices, tree offset, int dimen) { tree array; tree tmp; tree index; int n; array = gfc_build_indirect_ref (pointer); index = offset; for (n = 0; n < dimen; n++) { /* index = index + stride[n]*indices[n] */ tmp = gfc_conv_array_stride (se->expr, n); tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, indices[n], tmp); index = fold_build2 (PLUS_EXPR, gfc_array_index_type, index, tmp); } /* Result = data[index]. */ tmp = gfc_build_array_ref (array, index); /* Check we've used the correct number of dimensions. */ gcc_assert (TREE_CODE (TREE_TYPE (tmp)) != ARRAY_TYPE); se->expr = tmp; } /* Generate code to perform an array index bound check. */ static tree gfc_trans_array_bound_check (gfc_se * se, tree descriptor, tree index, int n) { tree cond; tree fault; tree tmp; if (!flag_bounds_check) return index; index = gfc_evaluate_now (index, &se->pre); /* Check lower bound. */ tmp = gfc_conv_array_lbound (descriptor, n); fault = fold_build2 (LT_EXPR, boolean_type_node, index, tmp); /* Check upper bound. */ tmp = gfc_conv_array_ubound (descriptor, n); cond = fold_build2 (GT_EXPR, boolean_type_node, index, tmp); fault = fold_build2 (TRUTH_OR_EXPR, boolean_type_node, fault, cond); gfc_trans_runtime_check (fault, gfc_strconst_fault, &se->pre); return index; } /* A reference to an array vector subscript. Uses recursion to handle nested vector subscripts. */ static tree gfc_conv_vector_array_index (gfc_se * se, tree index, gfc_ss * ss) { tree descsave; tree indices[GFC_MAX_DIMENSIONS]; gfc_array_ref *ar; gfc_ss_info *info; int n; gcc_assert (ss && ss->type == GFC_SS_VECTOR); /* Save the descriptor. */ descsave = se->expr; info = &ss->data.info; se->expr = info->descriptor; ar = &info->ref->u.ar; for (n = 0; n < ar->dimen; n++) { switch (ar->dimen_type[n]) { case DIMEN_ELEMENT: gcc_assert (info->subscript[n] != gfc_ss_terminator && info->subscript[n]->type == GFC_SS_SCALAR); indices[n] = info->subscript[n]->data.scalar.expr; break; case DIMEN_RANGE: indices[n] = index; break; case DIMEN_VECTOR: index = gfc_conv_vector_array_index (se, index, info->subscript[n]); indices[n] = gfc_trans_array_bound_check (se, info->descriptor, index, n); break; default: gcc_unreachable (); } } /* Get the index from the vector. */ gfc_conv_array_index_ref (se, info->data, indices, info->offset, ar->dimen); index = se->expr; /* Put the descriptor back. */ se->expr = descsave; return index; } /* Return the offset for an index. Performs bound checking for elemental dimensions. Single element references are processed separately. */ static tree gfc_conv_array_index_offset (gfc_se * se, gfc_ss_info * info, int dim, int i, gfc_array_ref * ar, tree stride) { tree index; /* Get the index into the array for this dimension. */ if (ar) { gcc_assert (ar->type != AR_ELEMENT); if (ar->dimen_type[dim] == DIMEN_ELEMENT) { gcc_assert (i == -1); /* Elemental dimension. */ gcc_assert (info->subscript[dim] && info->subscript[dim]->type == GFC_SS_SCALAR); /* We've already translated this value outside the loop. */ index = info->subscript[dim]->data.scalar.expr; index = gfc_trans_array_bound_check (se, info->descriptor, index, dim); } else { /* Scalarized dimension. */ gcc_assert (info && se->loop); /* Multiply the loop variable by the stride and delta. */ index = se->loop->loopvar[i]; index = fold_build2 (MULT_EXPR, gfc_array_index_type, index, info->stride[i]); index = fold_build2 (PLUS_EXPR, gfc_array_index_type, index, info->delta[i]); if (ar->dimen_type[dim] == DIMEN_VECTOR) { /* Handle vector subscripts. */ index = gfc_conv_vector_array_index (se, index, info->subscript[dim]); index = gfc_trans_array_bound_check (se, info->descriptor, index, dim); } else gcc_assert (ar->dimen_type[dim] == DIMEN_RANGE); } } else { /* Temporary array or derived type component. */ gcc_assert (se->loop); index = se->loop->loopvar[se->loop->order[i]]; if (!integer_zerop (info->delta[i])) index = fold_build2 (PLUS_EXPR, gfc_array_index_type, index, info->delta[i]); } /* Multiply by the stride. */ index = fold_build2 (MULT_EXPR, gfc_array_index_type, index, stride); return index; } /* Build a scalarized reference to an array. */ static void gfc_conv_scalarized_array_ref (gfc_se * se, gfc_array_ref * ar) { gfc_ss_info *info; tree index; tree tmp; int n; info = &se->ss->data.info; if (ar) n = se->loop->order[0]; else n = 0; index = gfc_conv_array_index_offset (se, info, info->dim[n], n, ar, info->stride0); /* Add the offset for this dimension to the stored offset for all other dimensions. */ index = fold_build2 (PLUS_EXPR, gfc_array_index_type, index, info->offset); tmp = gfc_build_indirect_ref (info->data); se->expr = gfc_build_array_ref (tmp, index); } /* Translate access of temporary array. */ void gfc_conv_tmp_array_ref (gfc_se * se) { se->string_length = se->ss->string_length; gfc_conv_scalarized_array_ref (se, NULL); } /* Build an array reference. se->expr already holds the array descriptor. This should be either a variable, indirect variable reference or component reference. For arrays which do not have a descriptor, se->expr will be the data pointer. a(i, j, k) = base[offset + i * stride[0] + j * stride[1] + k * stride[2]]*/ void gfc_conv_array_ref (gfc_se * se, gfc_array_ref * ar) { int n; tree index; tree tmp; tree stride; tree fault; gfc_se indexse; /* Handle scalarized references separately. */ if (ar->type != AR_ELEMENT) { gfc_conv_scalarized_array_ref (se, ar); return; } index = gfc_index_zero_node; fault = gfc_index_zero_node; /* Calculate the offsets from all the dimensions. */ for (n = 0; n < ar->dimen; n++) { /* Calculate the index for this dimension. */ gfc_init_se (&indexse, NULL); gfc_conv_expr_type (&indexse, ar->start[n], gfc_array_index_type); gfc_add_block_to_block (&se->pre, &indexse.pre); if (flag_bounds_check) { /* Check array bounds. */ tree cond; indexse.expr = gfc_evaluate_now (indexse.expr, &se->pre); tmp = gfc_conv_array_lbound (se->expr, n); cond = fold_build2 (LT_EXPR, boolean_type_node, indexse.expr, tmp); fault = fold_build2 (TRUTH_OR_EXPR, boolean_type_node, fault, cond); tmp = gfc_conv_array_ubound (se->expr, n); cond = fold_build2 (GT_EXPR, boolean_type_node, indexse.expr, tmp); fault = fold_build2 (TRUTH_OR_EXPR, boolean_type_node, fault, cond); } /* Multiply the index by the stride. */ stride = gfc_conv_array_stride (se->expr, n); tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, indexse.expr, stride); /* And add it to the total. */ index = fold_build2 (PLUS_EXPR, gfc_array_index_type, index, tmp); } if (flag_bounds_check) gfc_trans_runtime_check (fault, gfc_strconst_fault, &se->pre); tmp = gfc_conv_array_offset (se->expr); if (!integer_zerop (tmp)) index = fold_build2 (PLUS_EXPR, gfc_array_index_type, index, tmp); /* Access the calculated element. */ tmp = gfc_conv_array_data (se->expr); tmp = gfc_build_indirect_ref (tmp); se->expr = gfc_build_array_ref (tmp, index); } /* Generate the code to be executed immediately before entering a scalarization loop. */ static void gfc_trans_preloop_setup (gfc_loopinfo * loop, int dim, int flag, stmtblock_t * pblock) { tree index; tree stride; gfc_ss_info *info; gfc_ss *ss; gfc_se se; int i; /* This code will be executed before entering the scalarization loop for this dimension. */ for (ss = loop->ss; ss != gfc_ss_terminator; ss = ss->loop_chain) { if ((ss->useflags & flag) == 0) continue; if (ss->type != GFC_SS_SECTION && ss->type != GFC_SS_FUNCTION && ss->type != GFC_SS_CONSTRUCTOR && ss->type != GFC_SS_COMPONENT) continue; info = &ss->data.info; if (dim >= info->dimen) continue; if (dim == info->dimen - 1) { /* For the outermost loop calculate the offset due to any elemental dimensions. It will have been initialized with the base offset of the array. */ if (info->ref) { for (i = 0; i < info->ref->u.ar.dimen; i++) { if (info->ref->u.ar.dimen_type[i] != DIMEN_ELEMENT) continue; gfc_init_se (&se, NULL); se.loop = loop; se.expr = info->descriptor; stride = gfc_conv_array_stride (info->descriptor, i); index = gfc_conv_array_index_offset (&se, info, i, -1, &info->ref->u.ar, stride); gfc_add_block_to_block (pblock, &se.pre); info->offset = fold_build2 (PLUS_EXPR, gfc_array_index_type, info->offset, index); info->offset = gfc_evaluate_now (info->offset, pblock); } i = loop->order[0]; stride = gfc_conv_array_stride (info->descriptor, info->dim[i]); } else stride = gfc_conv_array_stride (info->descriptor, 0); /* Calculate the stride of the innermost loop. Hopefully this will allow the backend optimizers to do their stuff more effectively. */ info->stride0 = gfc_evaluate_now (stride, pblock); } else { /* Add the offset for the previous loop dimension. */ gfc_array_ref *ar; if (info->ref) { ar = &info->ref->u.ar; i = loop->order[dim + 1]; } else { ar = NULL; i = dim + 1; } gfc_init_se (&se, NULL); se.loop = loop; se.expr = info->descriptor; stride = gfc_conv_array_stride (info->descriptor, info->dim[i]); index = gfc_conv_array_index_offset (&se, info, info->dim[i], i, ar, stride); gfc_add_block_to_block (pblock, &se.pre); info->offset = fold_build2 (PLUS_EXPR, gfc_array_index_type, info->offset, index); info->offset = gfc_evaluate_now (info->offset, pblock); } /* Remember this offset for the second loop. */ if (dim == loop->temp_dim - 1) info->saved_offset = info->offset; } } /* Start a scalarized expression. Creates a scope and declares loop variables. */ void gfc_start_scalarized_body (gfc_loopinfo * loop, stmtblock_t * pbody) { int dim; int n; int flags; gcc_assert (!loop->array_parameter); for (dim = loop->dimen - 1; dim >= 0; dim--) { n = loop->order[dim]; gfc_start_block (&loop->code[n]); /* Create the loop variable. */ loop->loopvar[n] = gfc_create_var (gfc_array_index_type, "S"); if (dim < loop->temp_dim) flags = 3; else flags = 1; /* Calculate values that will be constant within this loop. */ gfc_trans_preloop_setup (loop, dim, flags, &loop->code[n]); } gfc_start_block (pbody); } /* Generates the actual loop code for a scalarization loop. */ static void gfc_trans_scalarized_loop_end (gfc_loopinfo * loop, int n, stmtblock_t * pbody) { stmtblock_t block; tree cond; tree tmp; tree loopbody; tree exit_label; loopbody = gfc_finish_block (pbody); /* Initialize the loopvar. */ gfc_add_modify_expr (&loop->code[n], loop->loopvar[n], loop->from[n]); exit_label = gfc_build_label_decl (NULL_TREE); /* Generate the loop body. */ gfc_init_block (&block); /* The exit condition. */ cond = build2 (GT_EXPR, boolean_type_node, loop->loopvar[n], loop->to[n]); tmp = build1_v (GOTO_EXPR, exit_label); TREE_USED (exit_label) = 1; tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt ()); gfc_add_expr_to_block (&block, tmp); /* The main body. */ gfc_add_expr_to_block (&block, loopbody); /* Increment the loopvar. */ tmp = build2 (PLUS_EXPR, gfc_array_index_type, loop->loopvar[n], gfc_index_one_node); gfc_add_modify_expr (&block, loop->loopvar[n], tmp); /* Build the loop. */ tmp = gfc_finish_block (&block); tmp = build1_v (LOOP_EXPR, tmp); gfc_add_expr_to_block (&loop->code[n], tmp); /* Add the exit label. */ tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (&loop->code[n], tmp); } /* Finishes and generates the loops for a scalarized expression. */ void gfc_trans_scalarizing_loops (gfc_loopinfo * loop, stmtblock_t * body) { int dim; int n; gfc_ss *ss; stmtblock_t *pblock; tree tmp; pblock = body; /* Generate the loops. */ for (dim = 0; dim < loop->dimen; dim++) { n = loop->order[dim]; gfc_trans_scalarized_loop_end (loop, n, pblock); loop->loopvar[n] = NULL_TREE; pblock = &loop->code[n]; } tmp = gfc_finish_block (pblock); gfc_add_expr_to_block (&loop->pre, tmp); /* Clear all the used flags. */ for (ss = loop->ss; ss; ss = ss->loop_chain) ss->useflags = 0; } /* Finish the main body of a scalarized expression, and start the secondary copying body. */ void gfc_trans_scalarized_loop_boundary (gfc_loopinfo * loop, stmtblock_t * body) { int dim; int n; stmtblock_t *pblock; gfc_ss *ss; pblock = body; /* We finish as many loops as are used by the temporary. */ for (dim = 0; dim < loop->temp_dim - 1; dim++) { n = loop->order[dim]; gfc_trans_scalarized_loop_end (loop, n, pblock); loop->loopvar[n] = NULL_TREE; pblock = &loop->code[n]; } /* We don't want to finish the outermost loop entirely. */ n = loop->order[loop->temp_dim - 1]; gfc_trans_scalarized_loop_end (loop, n, pblock); /* Restore the initial offsets. */ for (ss = loop->ss; ss != gfc_ss_terminator; ss = ss->loop_chain) { if ((ss->useflags & 2) == 0) continue; if (ss->type != GFC_SS_SECTION && ss->type != GFC_SS_FUNCTION && ss->type != GFC_SS_CONSTRUCTOR && ss->type != GFC_SS_COMPONENT) continue; ss->data.info.offset = ss->data.info.saved_offset; } /* Restart all the inner loops we just finished. */ for (dim = loop->temp_dim - 2; dim >= 0; dim--) { n = loop->order[dim]; gfc_start_block (&loop->code[n]); loop->loopvar[n] = gfc_create_var (gfc_array_index_type, "Q"); gfc_trans_preloop_setup (loop, dim, 2, &loop->code[n]); } /* Start a block for the secondary copying code. */ gfc_start_block (body); } /* Calculate the upper bound of an array section. */ static tree gfc_conv_section_upper_bound (gfc_ss * ss, int n, stmtblock_t * pblock) { int dim; gfc_ss *vecss; gfc_expr *end; tree desc; tree bound; gfc_se se; gcc_assert (ss->type == GFC_SS_SECTION); /* For vector array subscripts we want the size of the vector. */ dim = ss->data.info.dim[n]; vecss = ss; while (vecss->data.info.ref->u.ar.dimen_type[dim] == DIMEN_VECTOR) { vecss = vecss->data.info.subscript[dim]; gcc_assert (vecss && vecss->type == GFC_SS_VECTOR); dim = vecss->data.info.dim[0]; } gcc_assert (vecss->data.info.ref->u.ar.dimen_type[dim] == DIMEN_RANGE); end = vecss->data.info.ref->u.ar.end[dim]; desc = vecss->data.info.descriptor; if (end) { /* The upper bound was specified. */ gfc_init_se (&se, NULL); gfc_conv_expr_type (&se, end, gfc_array_index_type); gfc_add_block_to_block (pblock, &se.pre); bound = se.expr; } else { /* No upper bound was specified, so use the bound of the array. */ bound = gfc_conv_array_ubound (desc, dim); } return bound; } /* Calculate the lower bound of an array section. */ static void gfc_conv_section_startstride (gfc_loopinfo * loop, gfc_ss * ss, int n) { gfc_expr *start; gfc_expr *stride; gfc_ss *vecss; tree desc; gfc_se se; gfc_ss_info *info; int dim; info = &ss->data.info; dim = info->dim[n]; /* For vector array subscripts we want the size of the vector. */ vecss = ss; while (vecss->data.info.ref->u.ar.dimen_type[dim] == DIMEN_VECTOR) { vecss = vecss->data.info.subscript[dim]; gcc_assert (vecss && vecss->type == GFC_SS_VECTOR); /* Get the descriptors for the vector subscripts as well. */ if (!vecss->data.info.descriptor) gfc_conv_ss_descriptor (&loop->pre, vecss, !loop->array_parameter); dim = vecss->data.info.dim[0]; } gcc_assert (vecss->data.info.ref->u.ar.dimen_type[dim] == DIMEN_RANGE); start = vecss->data.info.ref->u.ar.start[dim]; stride = vecss->data.info.ref->u.ar.stride[dim]; desc = vecss->data.info.descriptor; /* Calculate the start of the range. For vector subscripts this will be the range of the vector. */ if (start) { /* Specified section start. */ gfc_init_se (&se, NULL); gfc_conv_expr_type (&se, start, gfc_array_index_type); gfc_add_block_to_block (&loop->pre, &se.pre); info->start[n] = se.expr; } else { /* No lower bound specified so use the bound of the array. */ info->start[n] = gfc_conv_array_lbound (desc, dim); } info->start[n] = gfc_evaluate_now (info->start[n], &loop->pre); /* Calculate the stride. */ if (stride == NULL) info->stride[n] = gfc_index_one_node; else { gfc_init_se (&se, NULL); gfc_conv_expr_type (&se, stride, gfc_array_index_type); gfc_add_block_to_block (&loop->pre, &se.pre); info->stride[n] = gfc_evaluate_now (se.expr, &loop->pre); } } /* Calculates the range start and stride for a SS chain. Also gets the descriptor and data pointer. The range of vector subscripts is the size of the vector. Array bounds are also checked. */ void gfc_conv_ss_startstride (gfc_loopinfo * loop) { int n; tree tmp; gfc_ss *ss; gfc_ss *vecss; tree desc; loop->dimen = 0; /* Determine the rank of the loop. */ for (ss = loop->ss; ss != gfc_ss_terminator && loop->dimen == 0; ss = ss->loop_chain) { switch (ss->type) { case GFC_SS_SECTION: case GFC_SS_CONSTRUCTOR: case GFC_SS_FUNCTION: case GFC_SS_COMPONENT: loop->dimen = ss->data.info.dimen; break; default: break; } } if (loop->dimen == 0) gfc_todo_error ("Unable to determine rank of expression"); /* Loop over all the SS in the chain. */ for (ss = loop->ss; ss != gfc_ss_terminator; ss = ss->loop_chain) { if (ss->expr && ss->expr->shape && !ss->shape) ss->shape = ss->expr->shape; switch (ss->type) { case GFC_SS_SECTION: /* Get the descriptor for the array. */ gfc_conv_ss_descriptor (&loop->pre, ss, !loop->array_parameter); for (n = 0; n < ss->data.info.dimen; n++) gfc_conv_section_startstride (loop, ss, n); break; case GFC_SS_CONSTRUCTOR: case GFC_SS_FUNCTION: for (n = 0; n < ss->data.info.dimen; n++) { ss->data.info.start[n] = gfc_index_zero_node; ss->data.info.stride[n] = gfc_index_one_node; } break; default: break; } } /* The rest is just runtime bound checking. */ if (flag_bounds_check) { stmtblock_t block; tree fault; tree bound; tree end; tree size[GFC_MAX_DIMENSIONS]; gfc_ss_info *info; int dim; gfc_start_block (&block); fault = integer_zero_node; for (n = 0; n < loop->dimen; n++) size[n] = NULL_TREE; for (ss = loop->ss; ss != gfc_ss_terminator; ss = ss->loop_chain) { if (ss->type != GFC_SS_SECTION) continue; /* TODO: range checking for mapped dimensions. */ info = &ss->data.info; /* This only checks scalarized dimensions, elemental dimensions are checked later. */ for (n = 0; n < loop->dimen; n++) { dim = info->dim[n]; vecss = ss; while (vecss->data.info.ref->u.ar.dimen_type[dim] == DIMEN_VECTOR) { vecss = vecss->data.info.subscript[dim]; gcc_assert (vecss && vecss->type == GFC_SS_VECTOR); dim = vecss->data.info.dim[0]; } gcc_assert (vecss->data.info.ref->u.ar.dimen_type[dim] == DIMEN_RANGE); desc = vecss->data.info.descriptor; /* Check lower bound. */ bound = gfc_conv_array_lbound (desc, dim); tmp = info->start[n]; tmp = fold_build2 (LT_EXPR, boolean_type_node, tmp, bound); fault = fold_build2 (TRUTH_OR_EXPR, boolean_type_node, fault, tmp); /* Check the upper bound. */ bound = gfc_conv_array_ubound (desc, dim); end = gfc_conv_section_upper_bound (ss, n, &block); tmp = fold_build2 (GT_EXPR, boolean_type_node, end, bound); fault = fold_build2 (TRUTH_OR_EXPR, boolean_type_node, fault, tmp); /* Check the section sizes match. */ tmp = fold_build2 (MINUS_EXPR, gfc_array_index_type, end, info->start[n]); tmp = fold_build2 (FLOOR_DIV_EXPR, gfc_array_index_type, tmp, info->stride[n]); /* We remember the size of the first section, and check all the others against this. */ if (size[n]) { tmp = fold_build2 (NE_EXPR, boolean_type_node, tmp, size[n]); fault = build2 (TRUTH_OR_EXPR, boolean_type_node, fault, tmp); } else size[n] = gfc_evaluate_now (tmp, &block); } } gfc_trans_runtime_check (fault, gfc_strconst_bounds, &block); tmp = gfc_finish_block (&block); gfc_add_expr_to_block (&loop->pre, tmp); } } /* Return true if the two SS could be aliased, i.e. both point to the same data object. */ /* TODO: resolve aliases based on frontend expressions. */ static int gfc_could_be_alias (gfc_ss * lss, gfc_ss * rss) { gfc_ref *lref; gfc_ref *rref; gfc_symbol *lsym; gfc_symbol *rsym; lsym = lss->expr->symtree->n.sym; rsym = rss->expr->symtree->n.sym; if (gfc_symbols_could_alias (lsym, rsym)) return 1; if (rsym->ts.type != BT_DERIVED && lsym->ts.type != BT_DERIVED) return 0; /* For derived types we must check all the component types. We can ignore array references as these will have the same base type as the previous component ref. */ for (lref = lss->expr->ref; lref != lss->data.info.ref; lref = lref->next) { if (lref->type != REF_COMPONENT) continue; if (gfc_symbols_could_alias (lref->u.c.sym, rsym)) return 1; for (rref = rss->expr->ref; rref != rss->data.info.ref; rref = rref->next) { if (rref->type != REF_COMPONENT) continue; if (gfc_symbols_could_alias (lref->u.c.sym, rref->u.c.sym)) return 1; } } for (rref = rss->expr->ref; rref != rss->data.info.ref; rref = rref->next) { if (rref->type != REF_COMPONENT) break; if (gfc_symbols_could_alias (rref->u.c.sym, lsym)) return 1; } return 0; } /* Resolve array data dependencies. Creates a temporary if required. */ /* TODO: Calc dependencies with gfc_expr rather than gfc_ss, and move to dependency.c. */ void gfc_conv_resolve_dependencies (gfc_loopinfo * loop, gfc_ss * dest, gfc_ss * rss) { gfc_ss *ss; gfc_ref *lref; gfc_ref *rref; gfc_ref *aref; int nDepend = 0; int temp_dim = 0; loop->temp_ss = NULL; aref = dest->data.info.ref; temp_dim = 0; for (ss = rss; ss != gfc_ss_terminator; ss = ss->next) { if (ss->type != GFC_SS_SECTION) continue; if (gfc_could_be_alias (dest, ss)) { nDepend = 1; break; } if (dest->expr->symtree->n.sym == ss->expr->symtree->n.sym) { lref = dest->expr->ref; rref = ss->expr->ref; nDepend = gfc_dep_resolver (lref, rref); #if 0 /* TODO : loop shifting. */ if (nDepend == 1) { /* Mark the dimensions for LOOP SHIFTING */ for (n = 0; n < loop->dimen; n++) { int dim = dest->data.info.dim[n]; if (lref->u.ar.dimen_type[dim] == DIMEN_VECTOR) depends[n] = 2; else if (! gfc_is_same_range (&lref->u.ar, &rref->u.ar, dim, 0)) depends[n] = 1; } /* Put all the dimensions with dependencies in the innermost loops. */ dim = 0; for (n = 0; n < loop->dimen; n++) { gcc_assert (loop->order[n] == n); if (depends[n]) loop->order[dim++] = n; } temp_dim = dim; for (n = 0; n < loop->dimen; n++) { if (! depends[n]) loop->order[dim++] = n; } gcc_assert (dim == loop->dimen); break; } #endif } } if (nDepend == 1) { loop->temp_ss = gfc_get_ss (); loop->temp_ss->type = GFC_SS_TEMP; loop->temp_ss->data.temp.type = gfc_get_element_type (TREE_TYPE (dest->data.info.descriptor)); loop->temp_ss->string_length = dest->string_length; loop->temp_ss->data.temp.dimen = loop->dimen; loop->temp_ss->next = gfc_ss_terminator; gfc_add_ss_to_loop (loop, loop->temp_ss); } else loop->temp_ss = NULL; } /* Initialize the scalarization loop. Creates the loop variables. Determines the range of the loop variables. Creates a temporary if required. Calculates how to transform from loop variables to array indices for each expression. Also generates code for scalar expressions which have been moved outside the loop. */ void gfc_conv_loop_setup (gfc_loopinfo * loop) { int n; int dim; gfc_ss_info *info; gfc_ss_info *specinfo; gfc_ss *ss; tree tmp; tree len; gfc_ss *loopspec[GFC_MAX_DIMENSIONS]; mpz_t *cshape; mpz_t i; mpz_init (i); for (n = 0; n < loop->dimen; n++) { loopspec[n] = NULL; /* We use one SS term, and use that to determine the bounds of the loop for this dimension. We try to pick the simplest term. */ for (ss = loop->ss; ss != gfc_ss_terminator; ss = ss->loop_chain) { if (ss->shape) { /* The frontend has worked out the size for us. */ loopspec[n] = ss; continue; } if (ss->type == GFC_SS_CONSTRUCTOR) { /* An unknown size constructor will always be rank one. Higher rank constructors will either have known shape, or still be wrapped in a call to reshape. */ gcc_assert (loop->dimen == 1); /* Try to figure out the size of the constructor. */ /* TODO: avoid this by making the frontend set the shape. */ gfc_get_array_cons_size (&i, ss->expr->value.constructor); /* A negative value means we failed. */ if (mpz_sgn (i) > 0) { mpz_sub_ui (i, i, 1); loop->to[n] = gfc_conv_mpz_to_tree (i, gfc_index_integer_kind); loopspec[n] = ss; } continue; } /* TODO: Pick the best bound if we have a choice between a function and something else. */ if (ss->type == GFC_SS_FUNCTION) { loopspec[n] = ss; continue; } if (ss->type != GFC_SS_SECTION) continue; if (loopspec[n]) specinfo = &loopspec[n]->data.info; else specinfo = NULL; info = &ss->data.info; /* Criteria for choosing a loop specifier (most important first): stride of one known stride known lower bound known upper bound */ if (!specinfo) loopspec[n] = ss; /* TODO: Is != constructor correct? */ else if (loopspec[n]->type != GFC_SS_CONSTRUCTOR) { if (integer_onep (info->stride[n]) && !integer_onep (specinfo->stride[n])) loopspec[n] = ss; else if (INTEGER_CST_P (info->stride[n]) && !INTEGER_CST_P (specinfo->stride[n])) loopspec[n] = ss; else if (INTEGER_CST_P (info->start[n]) && !INTEGER_CST_P (specinfo->start[n])) loopspec[n] = ss; /* We don't work out the upper bound. else if (INTEGER_CST_P (info->finish[n]) && ! INTEGER_CST_P (specinfo->finish[n])) loopspec[n] = ss; */ } } if (!loopspec[n]) gfc_todo_error ("Unable to find scalarization loop specifier"); info = &loopspec[n]->data.info; /* Set the extents of this range. */ cshape = loopspec[n]->shape; if (cshape && INTEGER_CST_P (info->start[n]) && INTEGER_CST_P (info->stride[n])) { loop->from[n] = info->start[n]; mpz_set (i, cshape[n]); mpz_sub_ui (i, i, 1); /* To = from + (size - 1) * stride. */ tmp = gfc_conv_mpz_to_tree (i, gfc_index_integer_kind); if (!integer_onep (info->stride[n])) tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, tmp, info->stride[n]); loop->to[n] = fold_build2 (PLUS_EXPR, gfc_array_index_type, loop->from[n], tmp); } else { loop->from[n] = info->start[n]; switch (loopspec[n]->type) { case GFC_SS_CONSTRUCTOR: gcc_assert (info->dimen == 1); gcc_assert (loop->to[n]); break; case GFC_SS_SECTION: loop->to[n] = gfc_conv_section_upper_bound (loopspec[n], n, &loop->pre); break; case GFC_SS_FUNCTION: /* The loop bound will be set when we generate the call. */ gcc_assert (loop->to[n] == NULL_TREE); break; default: gcc_unreachable (); } } /* Transform everything so we have a simple incrementing variable. */ if (integer_onep (info->stride[n])) info->delta[n] = gfc_index_zero_node; else { /* Set the delta for this section. */ info->delta[n] = gfc_evaluate_now (loop->from[n], &loop->pre); /* Number of iterations is (end - start + step) / step. with start = 0, this simplifies to last = end / step; for (i = 0; i<=last; i++){...}; */ tmp = fold_build2 (MINUS_EXPR, gfc_array_index_type, loop->to[n], loop->from[n]); tmp = fold_build2 (TRUNC_DIV_EXPR, gfc_array_index_type, tmp, info->stride[n]); loop->to[n] = gfc_evaluate_now (tmp, &loop->pre); /* Make the loop variable start at 0. */ loop->from[n] = gfc_index_zero_node; } } /* Add all the scalar code that can be taken out of the loops. This may include calculating the loop bounds, so do it before allocating the temporary. */ gfc_add_loop_ss_code (loop, loop->ss, false); /* If we want a temporary then create it. */ if (loop->temp_ss != NULL) { gcc_assert (loop->temp_ss->type == GFC_SS_TEMP); tmp = loop->temp_ss->data.temp.type; len = loop->temp_ss->string_length; n = loop->temp_ss->data.temp.dimen; memset (&loop->temp_ss->data.info, 0, sizeof (gfc_ss_info)); loop->temp_ss->type = GFC_SS_SECTION; loop->temp_ss->data.info.dimen = n; gfc_trans_allocate_temp_array (loop, &loop->temp_ss->data.info, tmp); } for (n = 0; n < loop->temp_dim; n++) loopspec[loop->order[n]] = NULL; mpz_clear (i); /* For array parameters we don't have loop variables, so don't calculate the translations. */ if (loop->array_parameter) return; /* Calculate the translation from loop variables to array indices. */ for (ss = loop->ss; ss != gfc_ss_terminator; ss = ss->loop_chain) { if (ss->type != GFC_SS_SECTION && ss->type != GFC_SS_COMPONENT) continue; info = &ss->data.info; for (n = 0; n < info->dimen; n++) { dim = info->dim[n]; /* If we are specifying the range the delta is already set. */ if (loopspec[n] != ss) { /* Calculate the offset relative to the loop variable. First multiply by the stride. */ tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, loop->from[n], info->stride[n]); /* Then subtract this from our starting value. */ tmp = fold_build2 (MINUS_EXPR, gfc_array_index_type, info->start[n], tmp); info->delta[n] = gfc_evaluate_now (tmp, &loop->pre); } } } } /* Fills in an array descriptor, and returns the size of the array. The size will be a simple_val, ie a variable or a constant. Also calculates the offset of the base. Returns the size of the array. { stride = 1; offset = 0; for (n = 0; n < rank; n++) { a.lbound[n] = specified_lower_bound; offset = offset + a.lbond[n] * stride; size = 1 - lbound; a.ubound[n] = specified_upper_bound; a.stride[n] = stride; size = ubound + size; //size = ubound + 1 - lbound stride = stride * size; } return (stride); } */ /*GCC ARRAYS*/ static tree gfc_array_init_size (tree descriptor, int rank, tree * poffset, gfc_expr ** lower, gfc_expr ** upper, stmtblock_t * pblock) { tree type; tree tmp; tree size; tree offset; tree stride; gfc_expr *ubound; gfc_se se; int n; type = TREE_TYPE (descriptor); stride = gfc_index_one_node; offset = gfc_index_zero_node; /* Set the dtype. */ tmp = gfc_conv_descriptor_dtype (descriptor); gfc_add_modify_expr (pblock, tmp, gfc_get_dtype (TREE_TYPE (descriptor))); for (n = 0; n < rank; n++) { /* We have 3 possibilities for determining the size of the array: lower == NULL => lbound = 1, ubound = upper[n] upper[n] = NULL => lbound = 1, ubound = lower[n] upper[n] != NULL => lbound = lower[n], ubound = upper[n] */ ubound = upper[n]; /* Set lower bound. */ gfc_init_se (&se, NULL); if (lower == NULL) se.expr = gfc_index_one_node; else { gcc_assert (lower[n]); if (ubound) { gfc_conv_expr_type (&se, lower[n], gfc_array_index_type); gfc_add_block_to_block (pblock, &se.pre); } else { se.expr = gfc_index_one_node; ubound = lower[n]; } } tmp = gfc_conv_descriptor_lbound (descriptor, gfc_rank_cst[n]); gfc_add_modify_expr (pblock, tmp, se.expr); /* Work out the offset for this component. */ tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, se.expr, stride); offset = fold_build2 (MINUS_EXPR, gfc_array_index_type, offset, tmp); /* Start the calculation for the size of this dimension. */ size = build2 (MINUS_EXPR, gfc_array_index_type, gfc_index_one_node, se.expr); /* Set upper bound. */ gfc_init_se (&se, NULL); gcc_assert (ubound); gfc_conv_expr_type (&se, ubound, gfc_array_index_type); gfc_add_block_to_block (pblock, &se.pre); tmp = gfc_conv_descriptor_ubound (descriptor, gfc_rank_cst[n]); gfc_add_modify_expr (pblock, tmp, se.expr); /* Store the stride. */ tmp = gfc_conv_descriptor_stride (descriptor, gfc_rank_cst[n]); gfc_add_modify_expr (pblock, tmp, stride); /* Calculate the size of this dimension. */ size = fold_build2 (PLUS_EXPR, gfc_array_index_type, se.expr, size); /* Multiply the stride by the number of elements in this dimension. */ stride = fold_build2 (MULT_EXPR, gfc_array_index_type, stride, size); stride = gfc_evaluate_now (stride, pblock); } /* The stride is the number of elements in the array, so multiply by the size of an element to get the total size. */ tmp = TYPE_SIZE_UNIT (gfc_get_element_type (type)); size = fold_build2 (MULT_EXPR, gfc_array_index_type, stride, tmp); if (poffset != NULL) { offset = gfc_evaluate_now (offset, pblock); *poffset = offset; } size = gfc_evaluate_now (size, pblock); return size; } /* Initializes the descriptor and generates a call to _gfor_allocate. Does the work for an ALLOCATE statement. */ /*GCC ARRAYS*/ void gfc_array_allocate (gfc_se * se, gfc_ref * ref, tree pstat) { tree tmp; tree pointer; tree allocate; tree offset; tree size; gfc_expr **lower; gfc_expr **upper; /* Figure out the size of the array. */ switch (ref->u.ar.type) { case AR_ELEMENT: lower = NULL; upper = ref->u.ar.start; break; case AR_FULL: gcc_assert (ref->u.ar.as->type == AS_EXPLICIT); lower = ref->u.ar.as->lower; upper = ref->u.ar.as->upper; break; case AR_SECTION: lower = ref->u.ar.start; upper = ref->u.ar.end; break; default: gcc_unreachable (); break; } size = gfc_array_init_size (se->expr, ref->u.ar.as->rank, &offset, lower, upper, &se->pre); /* Allocate memory to store the data. */ tmp = gfc_conv_descriptor_data_addr (se->expr); pointer = gfc_evaluate_now (tmp, &se->pre); if (TYPE_PRECISION (gfc_array_index_type) == 32) allocate = gfor_fndecl_allocate; else if (TYPE_PRECISION (gfc_array_index_type) == 64) allocate = gfor_fndecl_allocate64; else gcc_unreachable (); tmp = gfc_chainon_list (NULL_TREE, pointer); tmp = gfc_chainon_list (tmp, size); tmp = gfc_chainon_list (tmp, pstat); tmp = gfc_build_function_call (allocate, tmp); gfc_add_expr_to_block (&se->pre, tmp); tmp = gfc_conv_descriptor_offset (se->expr); gfc_add_modify_expr (&se->pre, tmp, offset); } /* Deallocate an array variable. Also used when an allocated variable goes out of scope. */ /*GCC ARRAYS*/ tree gfc_array_deallocate (tree descriptor, tree pstat) { tree var; tree tmp; stmtblock_t block; gfc_start_block (&block); /* Get a pointer to the data. */ tmp = gfc_conv_descriptor_data_addr (descriptor); var = gfc_evaluate_now (tmp, &block); /* Parameter is the address of the data component. */ tmp = gfc_chainon_list (NULL_TREE, var); tmp = gfc_chainon_list (tmp, pstat); tmp = gfc_build_function_call (gfor_fndecl_deallocate, tmp); gfc_add_expr_to_block (&block, tmp); return gfc_finish_block (&block); } /* Create an array constructor from an initialization expression. We assume the frontend already did any expansions and conversions. */ tree gfc_conv_array_initializer (tree type, gfc_expr * expr) { gfc_constructor *c; tree list; tree tmp; mpz_t maxval; gfc_se se; HOST_WIDE_INT hi; unsigned HOST_WIDE_INT lo; tree index, range; list = NULL_TREE; switch (expr->expr_type) { case EXPR_CONSTANT: case EXPR_STRUCTURE: /* A single scalar or derived type value. Create an array with all elements equal to that value. */ gfc_init_se (&se, NULL); if (expr->expr_type == EXPR_CONSTANT) gfc_conv_constant (&se, expr); else gfc_conv_structure (&se, expr, 1); tmp = TYPE_MAX_VALUE (TYPE_DOMAIN (type)); gcc_assert (tmp && INTEGER_CST_P (tmp)); hi = TREE_INT_CST_HIGH (tmp); lo = TREE_INT_CST_LOW (tmp); lo++; if (lo == 0) hi++; /* This will probably eat buckets of memory for large arrays. */ while (hi != 0 || lo != 0) { list = tree_cons (NULL_TREE, se.expr, list); if (lo == 0) hi--; lo--; } break; case EXPR_ARRAY: /* Create a list of all the elements. */ for (c = expr->value.constructor; c; c = c->next) { if (c->iterator) { /* Problems occur when we get something like integer :: a(lots) = (/(i, i=1,lots)/) */ /* TODO: Unexpanded array initializers. */ internal_error ("Possible frontend bug: array constructor not expanded"); } if (mpz_cmp_si (c->n.offset, 0) != 0) index = gfc_conv_mpz_to_tree (c->n.offset, gfc_index_integer_kind); else index = NULL_TREE; mpz_init (maxval); if (mpz_cmp_si (c->repeat, 0) != 0) { tree tmp1, tmp2; mpz_set (maxval, c->repeat); mpz_add (maxval, c->n.offset, maxval); mpz_sub_ui (maxval, maxval, 1); tmp2 = gfc_conv_mpz_to_tree (maxval, gfc_index_integer_kind); if (mpz_cmp_si (c->n.offset, 0) != 0) { mpz_add_ui (maxval, c->n.offset, 1); tmp1 = gfc_conv_mpz_to_tree (maxval, gfc_index_integer_kind); } else tmp1 = gfc_conv_mpz_to_tree (c->n.offset, gfc_index_integer_kind); range = build2 (RANGE_EXPR, integer_type_node, tmp1, tmp2); } else range = NULL; mpz_clear (maxval); gfc_init_se (&se, NULL); switch (c->expr->expr_type) { case EXPR_CONSTANT: gfc_conv_constant (&se, c->expr); if (range == NULL_TREE) list = tree_cons (index, se.expr, list); else { if (index != NULL_TREE) list = tree_cons (index, se.expr, list); list = tree_cons (range, se.expr, list); } break; case EXPR_STRUCTURE: gfc_conv_structure (&se, c->expr, 1); list = tree_cons (index, se.expr, list); break; default: gcc_unreachable (); } } /* We created the list in reverse order. */ list = nreverse (list); break; default: gcc_unreachable (); } /* Create a constructor from the list of elements. */ tmp = build1 (CONSTRUCTOR, type, list); TREE_CONSTANT (tmp) = 1; TREE_INVARIANT (tmp) = 1; return tmp; } /* Generate code to evaluate non-constant array bounds. Sets *poffset and returns the size (in elements) of the array. */ static tree gfc_trans_array_bounds (tree type, gfc_symbol * sym, tree * poffset, stmtblock_t * pblock) { gfc_array_spec *as; tree size; tree stride; tree offset; tree ubound; tree lbound; tree tmp; gfc_se se; int dim; as = sym->as; size = gfc_index_one_node; offset = gfc_index_zero_node; for (dim = 0; dim < as->rank; dim++) { /* Evaluate non-constant array bound expressions. */ lbound = GFC_TYPE_ARRAY_LBOUND (type, dim); if (as->lower[dim] && !INTEGER_CST_P (lbound)) { gfc_init_se (&se, NULL); gfc_conv_expr_type (&se, as->lower[dim], gfc_array_index_type); gfc_add_block_to_block (pblock, &se.pre); gfc_add_modify_expr (pblock, lbound, se.expr); } ubound = GFC_TYPE_ARRAY_UBOUND (type, dim); if (as->upper[dim] && !INTEGER_CST_P (ubound)) { gfc_init_se (&se, NULL); gfc_conv_expr_type (&se, as->upper[dim], gfc_array_index_type); gfc_add_block_to_block (pblock, &se.pre); gfc_add_modify_expr (pblock, ubound, se.expr); } /* The offset of this dimension. offset = offset - lbound * stride. */ tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, lbound, size); offset = fold_build2 (MINUS_EXPR, gfc_array_index_type, offset, tmp); /* The size of this dimension, and the stride of the next. */ if (dim + 1 < as->rank) stride = GFC_TYPE_ARRAY_STRIDE (type, dim + 1); else stride = NULL_TREE; if (ubound != NULL_TREE && !(stride && INTEGER_CST_P (stride))) { /* Calculate stride = size * (ubound + 1 - lbound). */ tmp = fold_build2 (MINUS_EXPR, gfc_array_index_type, gfc_index_one_node, lbound); tmp = fold_build2 (PLUS_EXPR, gfc_array_index_type, ubound, tmp); tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, size, tmp); if (stride) gfc_add_modify_expr (pblock, stride, tmp); else stride = gfc_evaluate_now (tmp, pblock); } size = stride; } *poffset = offset; return size; } /* Generate code to initialize/allocate an array variable. */ tree gfc_trans_auto_array_allocation (tree decl, gfc_symbol * sym, tree fnbody) { stmtblock_t block; tree type; tree tmp; tree fndecl; tree size; tree offset; bool onstack; gcc_assert (!(sym->attr.pointer || sym->attr.allocatable)); /* Do nothing for USEd variables. */ if (sym->attr.use_assoc) return fnbody; type = TREE_TYPE (decl); gcc_assert (GFC_ARRAY_TYPE_P (type)); onstack = TREE_CODE (type) != POINTER_TYPE; gfc_start_block (&block); /* Evaluate character string length. */ if (sym->ts.type == BT_CHARACTER && onstack && !INTEGER_CST_P (sym->ts.cl->backend_decl)) { gfc_trans_init_string_length (sym->ts.cl, &block); /* Emit a DECL_EXPR for this variable, which will cause the gimplifier to allocate storage, and all that good stuff. */ tmp = build1 (DECL_EXPR, TREE_TYPE (decl), decl); gfc_add_expr_to_block (&block, tmp); } if (onstack) { gfc_add_expr_to_block (&block, fnbody); return gfc_finish_block (&block); } type = TREE_TYPE (type); gcc_assert (!sym->attr.use_assoc); gcc_assert (!TREE_STATIC (decl)); gcc_assert (!sym->module); if (sym->ts.type == BT_CHARACTER && !INTEGER_CST_P (sym->ts.cl->backend_decl)) gfc_trans_init_string_length (sym->ts.cl, &block); size = gfc_trans_array_bounds (type, sym, &offset, &block); /* The size is the number of elements in the array, so multiply by the size of an element to get the total size. */ tmp = TYPE_SIZE_UNIT (gfc_get_element_type (type)); size = fold_build2 (MULT_EXPR, gfc_array_index_type, size, tmp); /* Allocate memory to hold the data. */ tmp = gfc_chainon_list (NULL_TREE, size); if (gfc_index_integer_kind == 4) fndecl = gfor_fndecl_internal_malloc; else if (gfc_index_integer_kind == 8) fndecl = gfor_fndecl_internal_malloc64; else gcc_unreachable (); tmp = gfc_build_function_call (fndecl, tmp); tmp = fold (convert (TREE_TYPE (decl), tmp)); gfc_add_modify_expr (&block, decl, tmp); /* Set offset of the array. */ if (TREE_CODE (GFC_TYPE_ARRAY_OFFSET (type)) == VAR_DECL) gfc_add_modify_expr (&block, GFC_TYPE_ARRAY_OFFSET (type), offset); /* Automatic arrays should not have initializers. */ gcc_assert (!sym->value); gfc_add_expr_to_block (&block, fnbody); /* Free the temporary. */ tmp = convert (pvoid_type_node, decl); tmp = gfc_chainon_list (NULL_TREE, tmp); tmp = gfc_build_function_call (gfor_fndecl_internal_free, tmp); gfc_add_expr_to_block (&block, tmp); return gfc_finish_block (&block); } /* Generate entry and exit code for g77 calling convention arrays. */ tree gfc_trans_g77_array (gfc_symbol * sym, tree body) { tree parm; tree type; locus loc; tree offset; tree tmp; stmtblock_t block; gfc_get_backend_locus (&loc); gfc_set_backend_locus (&sym->declared_at); /* Descriptor type. */ parm = sym->backend_decl; type = TREE_TYPE (parm); gcc_assert (GFC_ARRAY_TYPE_P (type)); gfc_start_block (&block); if (sym->ts.type == BT_CHARACTER && TREE_CODE (sym->ts.cl->backend_decl) == VAR_DECL) gfc_trans_init_string_length (sym->ts.cl, &block); /* Evaluate the bounds of the array. */ gfc_trans_array_bounds (type, sym, &offset, &block); /* Set the offset. */ if (TREE_CODE (GFC_TYPE_ARRAY_OFFSET (type)) == VAR_DECL) gfc_add_modify_expr (&block, GFC_TYPE_ARRAY_OFFSET (type), offset); /* Set the pointer itself if we aren't using the parameter directly. */ if (TREE_CODE (parm) != PARM_DECL) { tmp = convert (TREE_TYPE (parm), GFC_DECL_SAVED_DESCRIPTOR (parm)); gfc_add_modify_expr (&block, parm, tmp); } tmp = gfc_finish_block (&block); gfc_set_backend_locus (&loc); gfc_start_block (&block); /* Add the initialization code to the start of the function. */ gfc_add_expr_to_block (&block, tmp); gfc_add_expr_to_block (&block, body); return gfc_finish_block (&block); } /* Modify the descriptor of an array parameter so that it has the correct lower bound. Also move the upper bound accordingly. If the array is not packed, it will be copied into a temporary. For each dimension we set the new lower and upper bounds. Then we copy the stride and calculate the offset for this dimension. We also work out what the stride of a packed array would be, and see it the two match. If the array need repacking, we set the stride to the values we just calculated, recalculate the offset and copy the array data. Code is also added to copy the data back at the end of the function. */ tree gfc_trans_dummy_array_bias (gfc_symbol * sym, tree tmpdesc, tree body) { tree size; tree type; tree offset; locus loc; stmtblock_t block; stmtblock_t cleanup; tree lbound; tree ubound; tree dubound; tree dlbound; tree dumdesc; tree tmp; tree stmt; tree stride; tree stmt_packed; tree stmt_unpacked; tree partial; gfc_se se; int n; int checkparm; int no_repack; bool optional_arg; /* Do nothing for pointer and allocatable arrays. */ if (sym->attr.pointer || sym->attr.allocatable) return body; if (sym->attr.dummy && gfc_is_nodesc_array (sym)) return gfc_trans_g77_array (sym, body); gfc_get_backend_locus (&loc); gfc_set_backend_locus (&sym->declared_at); /* Descriptor type. */ type = TREE_TYPE (tmpdesc); gcc_assert (GFC_ARRAY_TYPE_P (type)); dumdesc = GFC_DECL_SAVED_DESCRIPTOR (tmpdesc); dumdesc = gfc_build_indirect_ref (dumdesc); gfc_start_block (&block); if (sym->ts.type == BT_CHARACTER && TREE_CODE (sym->ts.cl->backend_decl) == VAR_DECL) gfc_trans_init_string_length (sym->ts.cl, &block); checkparm = (sym->as->type == AS_EXPLICIT && flag_bounds_check); no_repack = !(GFC_DECL_PACKED_ARRAY (tmpdesc) || GFC_DECL_PARTIAL_PACKED_ARRAY (tmpdesc)); if (GFC_DECL_PARTIAL_PACKED_ARRAY (tmpdesc)) { /* For non-constant shape arrays we only check if the first dimension is contiguous. Repacking higher dimensions wouldn't gain us anything as we still don't know the array stride. */ partial = gfc_create_var (boolean_type_node, "partial"); TREE_USED (partial) = 1; tmp = gfc_conv_descriptor_stride (dumdesc, gfc_rank_cst[0]); tmp = fold_build2 (EQ_EXPR, boolean_type_node, tmp, integer_one_node); gfc_add_modify_expr (&block, partial, tmp); } else { partial = NULL_TREE; } /* The naming of stmt_unpacked and stmt_packed may be counter-intuitive here, however I think it does the right thing. */ if (no_repack) { /* Set the first stride. */ stride = gfc_conv_descriptor_stride (dumdesc, gfc_rank_cst[0]); stride = gfc_evaluate_now (stride, &block); tmp = build2 (EQ_EXPR, boolean_type_node, stride, integer_zero_node); tmp = build3 (COND_EXPR, gfc_array_index_type, tmp, gfc_index_one_node, stride); stride = GFC_TYPE_ARRAY_STRIDE (type, 0); gfc_add_modify_expr (&block, stride, tmp); /* Allow the user to disable array repacking. */ stmt_unpacked = NULL_TREE; } else { gcc_assert (integer_onep (GFC_TYPE_ARRAY_STRIDE (type, 0))); /* A library call to repack the array if necessary. */ tmp = GFC_DECL_SAVED_DESCRIPTOR (tmpdesc); tmp = gfc_chainon_list (NULL_TREE, tmp); stmt_unpacked = gfc_build_function_call (gfor_fndecl_in_pack, tmp); stride = gfc_index_one_node; } /* This is for the case where the array data is used directly without calling the repack function. */ if (no_repack || partial != NULL_TREE) stmt_packed = gfc_conv_descriptor_data_get (dumdesc); else stmt_packed = NULL_TREE; /* Assign the data pointer. */ if (stmt_packed != NULL_TREE && stmt_unpacked != NULL_TREE) { /* Don't repack unknown shape arrays when the first stride is 1. */ tmp = build3 (COND_EXPR, TREE_TYPE (stmt_packed), partial, stmt_packed, stmt_unpacked); } else tmp = stmt_packed != NULL_TREE ? stmt_packed : stmt_unpacked; gfc_add_modify_expr (&block, tmpdesc, fold_convert (type, tmp)); offset = gfc_index_zero_node; size = gfc_index_one_node; /* Evaluate the bounds of the array. */ for (n = 0; n < sym->as->rank; n++) { if (checkparm || !sym->as->upper[n]) { /* Get the bounds of the actual parameter. */ dubound = gfc_conv_descriptor_ubound (dumdesc, gfc_rank_cst[n]); dlbound = gfc_conv_descriptor_lbound (dumdesc, gfc_rank_cst[n]); } else { dubound = NULL_TREE; dlbound = NULL_TREE; } lbound = GFC_TYPE_ARRAY_LBOUND (type, n); if (!INTEGER_CST_P (lbound)) { gfc_init_se (&se, NULL); gfc_conv_expr_type (&se, sym->as->upper[n], gfc_array_index_type); gfc_add_block_to_block (&block, &se.pre); gfc_add_modify_expr (&block, lbound, se.expr); } ubound = GFC_TYPE_ARRAY_UBOUND (type, n); /* Set the desired upper bound. */ if (sym->as->upper[n]) { /* We know what we want the upper bound to be. */ if (!INTEGER_CST_P (ubound)) { gfc_init_se (&se, NULL); gfc_conv_expr_type (&se, sym->as->upper[n], gfc_array_index_type); gfc_add_block_to_block (&block, &se.pre); gfc_add_modify_expr (&block, ubound, se.expr); } /* Check the sizes match. */ if (checkparm) { /* Check (ubound(a) - lbound(a) == ubound(b) - lbound(b)). */ tmp = fold_build2 (MINUS_EXPR, gfc_array_index_type, ubound, lbound); stride = build2 (MINUS_EXPR, gfc_array_index_type, dubound, dlbound); tmp = fold_build2 (NE_EXPR, gfc_array_index_type, tmp, stride); gfc_trans_runtime_check (tmp, gfc_strconst_bounds, &block); } } else { /* For assumed shape arrays move the upper bound by the same amount as the lower bound. */ tmp = build2 (MINUS_EXPR, gfc_array_index_type, dubound, dlbound); tmp = fold_build2 (PLUS_EXPR, gfc_array_index_type, tmp, lbound); gfc_add_modify_expr (&block, ubound, tmp); } /* The offset of this dimension. offset = offset - lbound * stride. */ tmp = fold_build2 (MULT_EXPR, gfc_array_index_type, lbound, stride); offset = fold_build2 (MINUS_EXPR, gfc_array_index_type, offset, tmp); /* The size of this dimension, and the stride of the next. */ if (n + 1 < sym->as->rank) { stride = GFC_TYPE_ARRAY_STRIDE (type, n + 1); if (no_repack || partial != NULL_TREE) { stmt_unpacked = gfc_conv_descriptor_stride (dumdesc, gfc_rank_cst[n+1]); } /* Figure out the stride if not a known constant. */ if (!INTEGER_CST_P (stride)) { if (no_repack) stmt_packed = NULL_TREE; else { /* Calculate stride = size * (ubound + 1 - lbound). */ tmp = fold_build2 (MINUS_EXPR, gfc_array_index_type, gfc_index_one_node, lbound); tmp = fold_build2 (PLUS_EXPR, gfc_array_index_type, ubound, tmp); size = fold_build2 (MULT_EXPR, gfc_array_index_type, size, tmp); stmt_packed = size; } /* Assign the stride. */ if (stmt_packed != NULL_TREE && stmt_unpacked != NULL_TREE) tmp = build3 (COND_EXPR, gfc_array_index_type, partial, stmt_unpacked, stmt_packed); else tmp = (stmt_packed != NULL_TREE) ? stmt_packed : stmt_unpacked; gfc_add_modify_expr (&block, stride, tmp); } } } /* Set the offset. */ if (TREE_CODE (GFC_TYPE_ARRAY_OFFSET (type)) == VAR_DECL) gfc_add_modify_expr (&block, GFC_TYPE_ARRAY_OFFSET (type), offset); stmt = gfc_finish_block (&block); gfc_start_block (&block); /* Only do the entry/initialization code if the arg is present. */ dumdesc = GFC_DECL_SAVED_DESCRIPTOR (tmpdesc); optional_arg = (sym->attr.optional || (sym->ns->proc_name->attr.entry_master && sym->attr.dummy)); if (optional_arg) { tmp = gfc_conv_expr_present (sym); stmt = build3_v (COND_EXPR, tmp, stmt, build_empty_stmt ()); } gfc_add_expr_to_block (&block, stmt); /* Add the main function body. */ gfc_add_expr_to_block (&block, body); /* Cleanup code. */ if (!no_repack) { gfc_start_block (&cleanup); if (sym->attr.intent != INTENT_IN) { /* Copy the data back. */ tmp = gfc_chainon_list (NULL_TREE, dumdesc); tmp = gfc_chainon_list (tmp, tmpdesc); tmp = gfc_build_function_call (gfor_fndecl_in_unpack, tmp); gfc_add_expr_to_block (&cleanup, tmp); } /* Free the temporary. */ tmp = gfc_chainon_list (NULL_TREE, tmpdesc); tmp = gfc_build_function_call (gfor_fndecl_internal_free, tmp); gfc_add_expr_to_block (&cleanup, tmp); stmt = gfc_finish_block (&cleanup); /* Only do the cleanup if the array was repacked. */ tmp = gfc_build_indirect_ref (dumdesc); tmp = gfc_conv_descriptor_data_get (tmp); tmp = build2 (NE_EXPR, boolean_type_node, tmp, tmpdesc); stmt = build3_v (COND_EXPR, tmp, stmt, build_empty_stmt ()); if (optional_arg) { tmp = gfc_conv_expr_present (sym); stmt = build3_v (COND_EXPR, tmp, stmt, build_empty_stmt ()); } gfc_add_expr_to_block (&block, stmt); } /* We don't need to free any memory allocated by internal_pack as it will be freed at the end of the function by pop_context. */ return gfc_finish_block (&block); } /* Convert an array for passing as an actual parameter. Expressions and vector subscripts are evaluated and stored in a temporary, which is then passed. For whole arrays the descriptor is passed. For array sections a modified copy of the descriptor is passed, but using the original data. Also used for array pointer assignments by setting se->direct_byref. */ void gfc_conv_expr_descriptor (gfc_se * se, gfc_expr * expr, gfc_ss * ss) { gfc_loopinfo loop; gfc_ss *secss; gfc_ss_info *info; int need_tmp; int n; tree tmp; tree desc; stmtblock_t block; tree start; tree offset; int full; gfc_ss *vss; gfc_ref *ref; gcc_assert (ss != gfc_ss_terminator); /* TODO: Pass constant array constructors without a temporary. */ /* Special case things we know we can pass easily. */ switch (expr->expr_type) { case EXPR_VARIABLE: /* If we have a linear array section, we can pass it directly. Otherwise we need to copy it into a temporary. */ /* Find the SS for the array section. */ secss = ss; while (secss != gfc_ss_terminator && secss->type != GFC_SS_SECTION) secss = secss->next; gcc_assert (secss != gfc_ss_terminator); need_tmp = 0; for (n = 0; n < secss->data.info.dimen; n++) { vss = secss->data.info.subscript[secss->data.info.dim[n]]; if (vss && vss->type == GFC_SS_VECTOR) need_tmp = 1; } info = &secss->data.info; /* Get the descriptor for the array. */ gfc_conv_ss_descriptor (&se->pre, secss, 0); desc = info->descriptor; if (GFC_ARRAY_TYPE_P (TREE_TYPE (desc))) { /* Create a new descriptor if the array doesn't have one. */ full = 0; } else if (info->ref->u.ar.type == AR_FULL) full = 1; else if (se->direct_byref) full = 0; else { ref = info->ref; gcc_assert (ref->u.ar.type == AR_SECTION); full = 1; for (n = 0; n < ref->u.ar.dimen; n++) { /* Detect passing the full array as a section. This could do even more checking, but it doesn't seem worth it. */ if (ref->u.ar.start[n] || ref->u.ar.end[n] || (ref->u.ar.stride[n] && !gfc_expr_is_one (ref->u.ar.stride[n], 0))) { full = 0; break; } } } /* Check for substring references. */ ref = expr->ref; if (!need_tmp && ref && expr->ts.type == BT_CHARACTER) { while (ref->next) ref = ref->next; if (ref->type == REF_SUBSTRING) { /* In general character substrings need a copy. Character array strides are expressed as multiples of the element size (consistent with other array types), not in characters. */ full = 0; need_tmp = 1; } } if (full) { if (se->direct_byref) { /* Copy the descriptor for pointer assignments. */ gfc_add_modify_expr (&se->pre, se->expr, desc); } else if (se->want_pointer) { /* We pass full arrays directly. This means that pointers and allocatable arrays should also work. */ se->expr = gfc_build_addr_expr (NULL_TREE, desc); } else { se->expr = desc; } if (expr->ts.type == BT_CHARACTER) se->string_length = gfc_get_expr_charlen (expr); return; } break; case EXPR_FUNCTION: /* A transformational function return value will be a temporary array descriptor. We still need to go through the scalarizer to create the descriptor. Elemental functions ar handled as arbitrary expressions, i.e. copy to a temporary. */ secss = ss; /* Look for the SS for this function. */ while (secss != gfc_ss_terminator && (secss->type != GFC_SS_FUNCTION || secss->expr != expr)) secss = secss->next; if (se->direct_byref) { gcc_assert (secss != gfc_ss_terminator); /* For pointer assignments pass the descriptor directly. */ se->ss = secss; se->expr = gfc_build_addr_expr (NULL, se->expr); gfc_conv_expr (se, expr); return; } if (secss == gfc_ss_terminator) { /* Elemental function. */ need_tmp = 1; info = NULL; } else { /* Transformational function. */ info = &secss->data.info; need_tmp = 0; } break; default: /* Something complicated. Copy it into a temporary. */ need_tmp = 1; secss = NULL; info = NULL; break; } gfc_init_loopinfo (&loop); /* Associate the SS with the loop. */ gfc_add_ss_to_loop (&loop, ss); /* Tell the scalarizer not to bother creating loop variables, etc. */ if (!need_tmp) loop.array_parameter = 1; else gcc_assert (se->want_pointer && !se->direct_byref); /* Setup the scalarizing loops and bounds. */ gfc_conv_ss_startstride (&loop); if (need_tmp) { /* Tell the scalarizer to make a temporary. */ loop.temp_ss = gfc_get_ss (); loop.temp_ss->type = GFC_SS_TEMP; loop.temp_ss->next = gfc_ss_terminator; if (expr->ts.type == BT_CHARACTER) { gcc_assert (expr->ts.cl && expr->ts.cl->length && expr->ts.cl->length->expr_type == EXPR_CONSTANT); loop.temp_ss->string_length = gfc_conv_mpz_to_tree (expr->ts.cl->length->value.integer, expr->ts.cl->length->ts.kind); expr->ts.cl->backend_decl = loop.temp_ss->string_length; } loop.temp_ss->data.temp.type = gfc_typenode_for_spec (&expr->ts); /* ... which can hold our string, if present. */ if (expr->ts.type == BT_CHARACTER) { loop.temp_ss->string_length = TYPE_SIZE_UNIT (loop.temp_ss->data.temp.type); se->string_length = loop.temp_ss->string_length; } else loop.temp_ss->string_length = NULL; loop.temp_ss->data.temp.dimen = loop.dimen; gfc_add_ss_to_loop (&loop, loop.temp_ss); } gfc_conv_loop_setup (&loop); if (need_tmp) { /* Copy into a temporary and pass that. We don't need to copy the data back because expressions and vector subscripts must be INTENT_IN. */ /* TODO: Optimize passing function return values. */ gfc_se lse; gfc_se rse; /* Start the copying loops. */ gfc_mark_ss_chain_used (loop.temp_ss, 1); gfc_mark_ss_chain_used (ss, 1); gfc_start_scalarized_body (&loop, &block); /* Copy each data element. */ gfc_init_se (&lse, NULL); gfc_copy_loopinfo_to_se (&lse, &loop); gfc_init_se (&rse, NULL); gfc_copy_loopinfo_to_se (&rse, &loop); lse.ss = loop.temp_ss; rse.ss = ss; gfc_conv_scalarized_array_ref (&lse, NULL); if (expr->ts.type == BT_CHARACTER) { gfc_conv_expr (&rse, expr); rse.expr = gfc_build_indirect_ref (rse.expr); } else gfc_conv_expr_val (&rse, expr); gfc_add_block_to_block (&block, &rse.pre); gfc_add_block_to_block (&block, &lse.pre); gfc_add_modify_expr (&block, lse.expr, rse.expr); /* Finish the copying loops. */ gfc_trans_scalarizing_loops (&loop, &block); /* Set the first stride component to zero to indicate a temporary. */ desc = loop.temp_ss->data.info.descriptor; tmp = gfc_conv_descriptor_stride (desc, gfc_rank_cst[0]); gfc_add_modify_expr (&loop.pre, tmp, gfc_index_zero_node); gcc_assert (is_gimple_lvalue (desc)); se->expr = gfc_build_addr_expr (NULL, desc); } else if (expr->expr_type == EXPR_FUNCTION) { desc = info->descriptor; if (se->want_pointer) se->expr = gfc_build_addr_expr (NULL_TREE, desc); else se->expr = desc; if (expr->ts.type == BT_CHARACTER) se->string_length = expr->symtree->n.sym->ts.cl->backend_decl; } else { /* We pass sections without copying to a temporary. Make a new descriptor and point it at the section we want. The loop variable limits will be the limits of the section. A function may decide to repack the array to speed up access, but we're not bothered about that here. */ int dim; tree parm; tree parmtype; tree stride; tree from; tree to; tree base; /* Set the string_length for a character array. */ if (expr->ts.type == BT_CHARACTER) se->string_length = gfc_get_expr_charlen (expr); desc = info->descriptor; gcc_assert (secss && secss != gfc_ss_terminator); if (se->direct_byref) { /* For pointer assignments we fill in the destination. */ parm = se->expr; parmtype = TREE_TYPE (parm); } else { /* Otherwise make a new one. */ parmtype = gfc_get_element_type (TREE_TYPE (desc)); parmtype = gfc_get_array_type_bounds (parmtype, loop.dimen, loop.from, loop.to, 0); parm = gfc_create_var (parmtype, "parm"); } offset = gfc_index_zero_node; dim = 0; /* The following can be somewhat confusing. We have two descriptors, a new one and the original array. {parm, parmtype, dim} refer to the new one. {desc, type, n, secss, loop} refer to the original, which maybe a descriptorless array. The bounds of the scalarization are the bounds of the section. We don't have to worry about numeric overflows when calculating the offsets because all elements are within the array data. */ /* Set the dtype. */ tmp = gfc_conv_descriptor_dtype (parm); gfc_add_modify_expr (&loop.pre, tmp, gfc_get_dtype (parmtype)); if (se->direct_byref) base = gfc_index_zero_node; else base = NULL_TREE; for (n = 0; n < info->ref->u.ar.dimen; n++) { stride = gfc_conv_array_stride (desc, n); /* Work out the offset. */ if (info->ref->u.ar.dimen_type[n] == DIMEN_ELEMENT) { gcc_assert (info->subscript[n] && info->subscript[n]->type == GFC_SS_SCALAR); start = info->subscript[n]->data.scalar.expr; } else { /* Check we haven't somehow got out of sync. */ gcc_assert (info->dim[dim] == n); /* Evaluate and remember the start of the section. */ start = info->start[dim]; stride = gfc_evaluate_now (stride, &loop.pre); } tmp = gfc_conv_array_lbound (desc, n); tmp = fold_build2 (MINUS_EXPR, TREE_TYPE (tmp), start, tmp); tmp = fold_build2 (MULT_EXPR, TREE_TYPE (tmp), tmp, stride); offset = fold_build2 (PLUS_EXPR, TREE_TYPE (tmp), offset, tmp); if (info->ref->u.ar.dimen_type[n] == DIMEN_ELEMENT) { /* For elemental dimensions, we only need the offset. */ continue; } /* Vector subscripts need copying and are handled elsewhere. */ gcc_assert (info->ref->u.ar.dimen_type[n] == DIMEN_RANGE); /* Set the new lower bound. */ from = loop.from[dim]; to = loop.to[dim]; if (!integer_onep (from)) { /* Make sure the new section starts at 1. */ tmp = fold_build2 (MINUS_EXPR, gfc_array_index_type, gfc_index_one_node, from); to = fold_build2 (PLUS_EXPR, gfc_array_index_type, to, tmp); from = gfc_index_one_node; } tmp = gfc_conv_descriptor_lbound (parm, gfc_rank_cst[dim]); gfc_add_modify_expr (&loop.pre, tmp, from); /* Set the new upper bound. */ tmp = gfc_conv_descriptor_ubound (parm, gfc_rank_cst[dim]); gfc_add_modify_expr (&loop.pre, tmp, to); /* Multiply the stride by the section stride to get the total stride. */ stride = fold_build2 (MULT_EXPR, gfc_array_index_type, stride, info->stride[dim]); if (se->direct_byref) base = fold_build2 (MINUS_EXPR, TREE_TYPE (base), base, stride); /* Store the new stride. */ tmp = gfc_conv_descriptor_stride (parm, gfc_rank_cst[dim]); gfc_add_modify_expr (&loop.pre, tmp, stride); dim++; } /* Point the data pointer at the first element in the section. */ tmp = gfc_conv_array_data (desc); tmp = gfc_build_indirect_ref (tmp); tmp = gfc_build_array_ref (tmp, offset); offset = gfc_build_addr_expr (gfc_array_dataptr_type (desc), tmp); gfc_conv_descriptor_data_set (&loop.pre, parm, offset); if (se->direct_byref) { /* Set the offset. */ tmp = gfc_conv_descriptor_offset (parm); gfc_add_modify_expr (&loop.pre, tmp, base); } else { /* Only the callee knows what the correct offset it, so just set it to zero here. */ tmp = gfc_conv_descriptor_offset (parm); gfc_add_modify_expr (&loop.pre, tmp, gfc_index_zero_node); } if (!se->direct_byref) { /* Get a pointer to the new descriptor. */ if (se->want_pointer) se->expr = gfc_build_addr_expr (NULL, parm); else se->expr = parm; } } gfc_add_block_to_block (&se->pre, &loop.pre); gfc_add_block_to_block (&se->post, &loop.post); /* Cleanup the scalarizer. */ gfc_cleanup_loop (&loop); } /* Convert an array for passing as an actual parameter. */ /* TODO: Optimize passing g77 arrays. */ void gfc_conv_array_parameter (gfc_se * se, gfc_expr * expr, gfc_ss * ss, int g77) { tree ptr; tree desc; tree tmp; tree stmt; gfc_symbol *sym; stmtblock_t block; /* Passing address of the array if it is not pointer or assumed-shape. */ if (expr->expr_type == EXPR_VARIABLE && expr->ref->u.ar.type == AR_FULL && g77) { sym = expr->symtree->n.sym; tmp = gfc_get_symbol_decl (sym); if (sym->ts.type == BT_CHARACTER) se->string_length = sym->ts.cl->backend_decl; if (!sym->attr.pointer && sym->as->type != AS_ASSUMED_SHAPE && !sym->attr.allocatable) { /* Some variables are declared directly, others are declared as pointers and allocated on the heap. */ if (sym->attr.dummy || POINTER_TYPE_P (TREE_TYPE (tmp))) se->expr = tmp; else se->expr = gfc_build_addr_expr (NULL, tmp); return; } if (sym->attr.allocatable) { se->expr = gfc_conv_array_data (tmp); return; } } se->want_pointer = 1; gfc_conv_expr_descriptor (se, expr, ss); if (g77) { desc = se->expr; /* Repack the array. */ tmp = gfc_chainon_list (NULL_TREE, desc); ptr = gfc_build_function_call (gfor_fndecl_in_pack, tmp); ptr = gfc_evaluate_now (ptr, &se->pre); se->expr = ptr; gfc_start_block (&block); /* Copy the data back. */ tmp = gfc_chainon_list (NULL_TREE, desc); tmp = gfc_chainon_list (tmp, ptr); tmp = gfc_build_function_call (gfor_fndecl_in_unpack, tmp); gfc_add_expr_to_block (&block, tmp); /* Free the temporary. */ tmp = convert (pvoid_type_node, ptr); tmp = gfc_chainon_list (NULL_TREE, tmp); tmp = gfc_build_function_call (gfor_fndecl_internal_free, tmp); gfc_add_expr_to_block (&block, tmp); stmt = gfc_finish_block (&block); gfc_init_block (&block); /* Only if it was repacked. This code needs to be executed before the loop cleanup code. */ tmp = gfc_build_indirect_ref (desc); tmp = gfc_conv_array_data (tmp); tmp = build2 (NE_EXPR, boolean_type_node, ptr, tmp); tmp = build3_v (COND_EXPR, tmp, stmt, build_empty_stmt ()); gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&block, &se->post); gfc_init_block (&se->post); gfc_add_block_to_block (&se->post, &block); } } /* NULLIFY an allocated/pointer array on function entry, free it on exit. */ tree gfc_trans_deferred_array (gfc_symbol * sym, tree body) { tree type; tree tmp; tree descriptor; tree deallocate; stmtblock_t block; stmtblock_t fnblock; locus loc; /* Make sure the frontend gets these right. */ if (!(sym->attr.pointer || sym->attr.allocatable)) fatal_error ("Possible frontend bug: Deferred array size without pointer or allocatable attribute."); gfc_init_block (&fnblock); gcc_assert (TREE_CODE (sym->backend_decl) == VAR_DECL); if (sym->ts.type == BT_CHARACTER && !INTEGER_CST_P (sym->ts.cl->backend_decl)) gfc_trans_init_string_length (sym->ts.cl, &fnblock); /* Parameter and use associated variables don't need anything special. */ if (sym->attr.dummy || sym->attr.use_assoc) { gfc_add_expr_to_block (&fnblock, body); return gfc_finish_block (&fnblock); } gfc_get_backend_locus (&loc); gfc_set_backend_locus (&sym->declared_at); descriptor = sym->backend_decl; if (TREE_STATIC (descriptor)) { /* SAVEd variables are not freed on exit. */ gfc_trans_static_array_pointer (sym); return body; } /* Get the descriptor type. */ type = TREE_TYPE (sym->backend_decl); gcc_assert (GFC_DESCRIPTOR_TYPE_P (type)); /* NULLIFY the data pointer. */ gfc_conv_descriptor_data_set (&fnblock, descriptor, null_pointer_node); gfc_add_expr_to_block (&fnblock, body); gfc_set_backend_locus (&loc); /* Allocatable arrays need to be freed when they go out of scope. */ if (sym->attr.allocatable) { gfc_start_block (&block); /* Deallocate if still allocated at the end of the procedure. */ deallocate = gfc_array_deallocate (descriptor, null_pointer_node); tmp = gfc_conv_descriptor_data_get (descriptor); tmp = build2 (NE_EXPR, boolean_type_node, tmp, build_int_cst (TREE_TYPE (tmp), 0)); tmp = build3_v (COND_EXPR, tmp, deallocate, build_empty_stmt ()); gfc_add_expr_to_block (&block, tmp); tmp = gfc_finish_block (&block); gfc_add_expr_to_block (&fnblock, tmp); } return gfc_finish_block (&fnblock); } /************ Expression Walking Functions ******************/ /* Walk a variable reference. Possible extension - multiple component subscripts. x(:,:) = foo%a(:)%b(:) Transforms to forall (i=..., j=...) x(i,j) = foo%a(j)%b(i) end forall This adds a fair amout of complexity because you need to deal with more than one ref. Maybe handle in a similar manner to vector subscripts. Maybe not worth the effort. */ static gfc_ss * gfc_walk_variable_expr (gfc_ss * ss, gfc_expr * expr) { gfc_ref *ref; gfc_array_ref *ar; gfc_ss *newss; gfc_ss *head; int n; for (ref = expr->ref; ref; ref = ref->next) { /* We're only interested in array sections. */ if (ref->type != REF_ARRAY) continue; ar = &ref->u.ar; switch (ar->type) { case AR_ELEMENT: /* TODO: Take elemental array references out of scalarization loop. */ break; case AR_FULL: newss = gfc_get_ss (); newss->type = GFC_SS_SECTION; newss->expr = expr; newss->next = ss; newss->data.info.dimen = ar->as->rank; newss->data.info.ref = ref; /* Make sure array is the same as array(:,:), this way we don't need to special case all the time. */ ar->dimen = ar->as->rank; for (n = 0; n < ar->dimen; n++) { newss->data.info.dim[n] = n; ar->dimen_type[n] = DIMEN_RANGE; gcc_assert (ar->start[n] == NULL); gcc_assert (ar->end[n] == NULL); gcc_assert (ar->stride[n] == NULL); } return newss; case AR_SECTION: newss = gfc_get_ss (); newss->type = GFC_SS_SECTION; newss->expr = expr; newss->next = ss; newss->data.info.dimen = 0; newss->data.info.ref = ref; head = newss; /* We add SS chains for all the subscripts in the section. */ for (n = 0; n < ar->dimen; n++) { gfc_ss *indexss; switch (ar->dimen_type[n]) { case DIMEN_ELEMENT: /* Add SS for elemental (scalar) subscripts. */ gcc_assert (ar->start[n]); indexss = gfc_get_ss (); indexss->type = GFC_SS_SCALAR; indexss->expr = ar->start[n]; indexss->next = gfc_ss_terminator; indexss->loop_chain = gfc_ss_terminator; newss->data.info.subscript[n] = indexss; break; case DIMEN_RANGE: /* We don't add anything for sections, just remember this dimension for later. */ newss->data.info.dim[newss->data.info.dimen] = n; newss->data.info.dimen++; break; case DIMEN_VECTOR: /* Get a SS for the vector. This will not be added to the chain directly. */ indexss = gfc_walk_expr (ar->start[n]); if (indexss == gfc_ss_terminator) internal_error ("scalar vector subscript???"); /* We currently only handle really simple vector subscripts. */ if (indexss->next != gfc_ss_terminator) gfc_todo_error ("vector subscript expressions"); indexss->loop_chain = gfc_ss_terminator; /* Mark this as a vector subscript. We don't add this directly into the chain, but as a subscript of the existing SS for this term. */ indexss->type = GFC_SS_VECTOR; newss->data.info.subscript[n] = indexss; /* Also remember this dimension. */ newss->data.info.dim[newss->data.info.dimen] = n; newss->data.info.dimen++; break; default: /* We should know what sort of section it is by now. */ gcc_unreachable (); } } /* We should have at least one non-elemental dimension. */ gcc_assert (newss->data.info.dimen > 0); return head; break; default: /* We should know what sort of section it is by now. */ gcc_unreachable (); } } return ss; } /* Walk an expression operator. If only one operand of a binary expression is scalar, we must also add the scalar term to the SS chain. */ static gfc_ss * gfc_walk_op_expr (gfc_ss * ss, gfc_expr * expr) { gfc_ss *head; gfc_ss *head2; gfc_ss *newss; head = gfc_walk_subexpr (ss, expr->value.op.op1); if (expr->value.op.op2 == NULL) head2 = head; else head2 = gfc_walk_subexpr (head, expr->value.op.op2); /* All operands are scalar. Pass back and let the caller deal with it. */ if (head2 == ss) return head2; /* All operands require scalarization. */ if (head != ss && (expr->value.op.op2 == NULL || head2 != head)) return head2; /* One of the operands needs scalarization, the other is scalar. Create a gfc_ss for the scalar expression. */ newss = gfc_get_ss (); newss->type = GFC_SS_SCALAR; if (head == ss) { /* First operand is scalar. We build the chain in reverse order, so add the scarar SS after the second operand. */ head = head2; while (head && head->next != ss) head = head->next; /* Check we haven't somehow broken the chain. */ gcc_assert (head); newss->next = ss; head->next = newss; newss->expr = expr->value.op.op1; } else /* head2 == head */ { gcc_assert (head2 == head); /* Second operand is scalar. */ newss->next = head2; head2 = newss; newss->expr = expr->value.op.op2; } return head2; } /* Reverse a SS chain. */ static gfc_ss * gfc_reverse_ss (gfc_ss * ss) { gfc_ss *next; gfc_ss *head; gcc_assert (ss != NULL); head = gfc_ss_terminator; while (ss != gfc_ss_terminator) { next = ss->next; /* Check we didn't somehow break the chain. */ gcc_assert (next != NULL); ss->next = head; head = ss; ss = next; } return (head); } /* Walk the arguments of an elemental function. */ gfc_ss * gfc_walk_elemental_function_args (gfc_ss * ss, gfc_expr * expr, gfc_ss_type type) { gfc_actual_arglist *arg; int scalar; gfc_ss *head; gfc_ss *tail; gfc_ss *newss; head = gfc_ss_terminator; tail = NULL; scalar = 1; for (arg = expr->value.function.actual; arg; arg = arg->next) { if (!arg->expr) continue; newss = gfc_walk_subexpr (head, arg->expr); if (newss == head) { /* Scalar argument. */ newss = gfc_get_ss (); newss->type = type; newss->expr = arg->expr; newss->next = head; } else scalar = 0; head = newss; if (!tail) { tail = head; while (tail->next != gfc_ss_terminator) tail = tail->next; } } if (scalar) { /* If all the arguments are scalar we don't need the argument SS. */ gfc_free_ss_chain (head); /* Pass it back. */ return ss; } /* Add it onto the existing chain. */ tail->next = ss; return head; } /* Walk a function call. Scalar functions are passed back, and taken out of scalarization loops. For elemental functions we walk their arguments. The result of functions returning arrays is stored in a temporary outside the loop, so that the function is only called once. Hence we do not need to walk their arguments. */ static gfc_ss * gfc_walk_function_expr (gfc_ss * ss, gfc_expr * expr) { gfc_ss *newss; gfc_intrinsic_sym *isym; gfc_symbol *sym; isym = expr->value.function.isym; /* Handle intrinsic functions separately. */ if (isym) return gfc_walk_intrinsic_function (ss, expr, isym); sym = expr->value.function.esym; if (!sym) sym = expr->symtree->n.sym; /* A function that returns arrays. */ if (gfc_return_by_reference (sym) && sym->result->attr.dimension) { newss = gfc_get_ss (); newss->type = GFC_SS_FUNCTION; newss->expr = expr; newss->next = ss; newss->data.info.dimen = expr->rank; return newss; } /* Walk the parameters of an elemental function. For now we always pass by reference. */ if (sym->attr.elemental) return gfc_walk_elemental_function_args (ss, expr, GFC_SS_REFERENCE); /* Scalar functions are OK as these are evaluated outside the scalarization loop. Pass back and let the caller deal with it. */ return ss; } /* An array temporary is constructed for array constructors. */ static gfc_ss * gfc_walk_array_constructor (gfc_ss * ss, gfc_expr * expr) { gfc_ss *newss; int n; newss = gfc_get_ss (); newss->type = GFC_SS_CONSTRUCTOR; newss->expr = expr; newss->next = ss; newss->data.info.dimen = expr->rank; for (n = 0; n < expr->rank; n++) newss->data.info.dim[n] = n; return newss; } /* Walk an expression. Add walked expressions to the head of the SS chain. A wholly scalar expression will not be added. */ static gfc_ss * gfc_walk_subexpr (gfc_ss * ss, gfc_expr * expr) { gfc_ss *head; switch (expr->expr_type) { case EXPR_VARIABLE: head = gfc_walk_variable_expr (ss, expr); return head; case EXPR_OP: head = gfc_walk_op_expr (ss, expr); return head; case EXPR_FUNCTION: head = gfc_walk_function_expr (ss, expr); return head; case EXPR_CONSTANT: case EXPR_NULL: case EXPR_STRUCTURE: /* Pass back and let the caller deal with it. */ break; case EXPR_ARRAY: head = gfc_walk_array_constructor (ss, expr); return head; case EXPR_SUBSTRING: /* Pass back and let the caller deal with it. */ break; default: internal_error ("bad expression type during walk (%d)", expr->expr_type); } return ss; } /* Entry point for expression walking. A return value equal to the passed chain means this is a scalar expression. It is up to the caller to take whatever action is necessary to translate these. */ gfc_ss * gfc_walk_expr (gfc_expr * expr) { gfc_ss *res; res = gfc_walk_subexpr (gfc_ss_terminator, expr); return gfc_reverse_ss (res); }