/* Routines for manipulation of expression nodes.
Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008,
2009, 2010, 2011
Free Software Foundation, Inc.
Contributed by Andy Vaught
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free
Software Foundation; either version 3, or (at your option) any later
version.
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING3. If not see
. */
#include "config.h"
#include "system.h"
#include "gfortran.h"
#include "arith.h"
#include "match.h"
#include "target-memory.h" /* for gfc_convert_boz */
#include "constructor.h"
/* The following set of functions provide access to gfc_expr* of
various types - actual all but EXPR_FUNCTION and EXPR_VARIABLE.
There are two functions available elsewhere that provide
slightly different flavours of variables. Namely:
expr.c (gfc_get_variable_expr)
symbol.c (gfc_lval_expr_from_sym)
TODO: Merge these functions, if possible. */
/* Get a new expression node. */
gfc_expr *
gfc_get_expr (void)
{
gfc_expr *e;
e = XCNEW (gfc_expr);
gfc_clear_ts (&e->ts);
e->shape = NULL;
e->ref = NULL;
e->symtree = NULL;
return e;
}
/* Get a new expression node that is an array constructor
of given type and kind. */
gfc_expr *
gfc_get_array_expr (bt type, int kind, locus *where)
{
gfc_expr *e;
e = gfc_get_expr ();
e->expr_type = EXPR_ARRAY;
e->value.constructor = NULL;
e->rank = 1;
e->shape = NULL;
e->ts.type = type;
e->ts.kind = kind;
if (where)
e->where = *where;
return e;
}
/* Get a new expression node that is the NULL expression. */
gfc_expr *
gfc_get_null_expr (locus *where)
{
gfc_expr *e;
e = gfc_get_expr ();
e->expr_type = EXPR_NULL;
e->ts.type = BT_UNKNOWN;
if (where)
e->where = *where;
return e;
}
/* Get a new expression node that is an operator expression node. */
gfc_expr *
gfc_get_operator_expr (locus *where, gfc_intrinsic_op op,
gfc_expr *op1, gfc_expr *op2)
{
gfc_expr *e;
e = gfc_get_expr ();
e->expr_type = EXPR_OP;
e->value.op.op = op;
e->value.op.op1 = op1;
e->value.op.op2 = op2;
if (where)
e->where = *where;
return e;
}
/* Get a new expression node that is an structure constructor
of given type and kind. */
gfc_expr *
gfc_get_structure_constructor_expr (bt type, int kind, locus *where)
{
gfc_expr *e;
e = gfc_get_expr ();
e->expr_type = EXPR_STRUCTURE;
e->value.constructor = NULL;
e->ts.type = type;
e->ts.kind = kind;
if (where)
e->where = *where;
return e;
}
/* Get a new expression node that is an constant of given type and kind. */
gfc_expr *
gfc_get_constant_expr (bt type, int kind, locus *where)
{
gfc_expr *e;
if (!where)
gfc_internal_error ("gfc_get_constant_expr(): locus 'where' cannot be NULL");
e = gfc_get_expr ();
e->expr_type = EXPR_CONSTANT;
e->ts.type = type;
e->ts.kind = kind;
e->where = *where;
switch (type)
{
case BT_INTEGER:
mpz_init (e->value.integer);
break;
case BT_REAL:
gfc_set_model_kind (kind);
mpfr_init (e->value.real);
break;
case BT_COMPLEX:
gfc_set_model_kind (kind);
mpc_init2 (e->value.complex, mpfr_get_default_prec());
break;
default:
break;
}
return e;
}
/* Get a new expression node that is an string constant.
If no string is passed, a string of len is allocated,
blanked and null-terminated. */
gfc_expr *
gfc_get_character_expr (int kind, locus *where, const char *src, int len)
{
gfc_expr *e;
gfc_char_t *dest;
if (!src)
{
dest = gfc_get_wide_string (len + 1);
gfc_wide_memset (dest, ' ', len);
dest[len] = '\0';
}
else
dest = gfc_char_to_widechar (src);
e = gfc_get_constant_expr (BT_CHARACTER, kind,
where ? where : &gfc_current_locus);
e->value.character.string = dest;
e->value.character.length = len;
return e;
}
/* Get a new expression node that is an integer constant. */
gfc_expr *
gfc_get_int_expr (int kind, locus *where, int value)
{
gfc_expr *p;
p = gfc_get_constant_expr (BT_INTEGER, kind,
where ? where : &gfc_current_locus);
mpz_set_si (p->value.integer, value);
return p;
}
/* Get a new expression node that is a logical constant. */
gfc_expr *
gfc_get_logical_expr (int kind, locus *where, bool value)
{
gfc_expr *p;
p = gfc_get_constant_expr (BT_LOGICAL, kind,
where ? where : &gfc_current_locus);
p->value.logical = value;
return p;
}
gfc_expr *
gfc_get_iokind_expr (locus *where, io_kind k)
{
gfc_expr *e;
/* Set the types to something compatible with iokind. This is needed to
get through gfc_free_expr later since iokind really has no Basic Type,
BT, of its own. */
e = gfc_get_expr ();
e->expr_type = EXPR_CONSTANT;
e->ts.type = BT_LOGICAL;
e->value.iokind = k;
e->where = *where;
return e;
}
/* Given an expression pointer, return a copy of the expression. This
subroutine is recursive. */
gfc_expr *
gfc_copy_expr (gfc_expr *p)
{
gfc_expr *q;
gfc_char_t *s;
char *c;
if (p == NULL)
return NULL;
q = gfc_get_expr ();
*q = *p;
switch (q->expr_type)
{
case EXPR_SUBSTRING:
s = gfc_get_wide_string (p->value.character.length + 1);
q->value.character.string = s;
memcpy (s, p->value.character.string,
(p->value.character.length + 1) * sizeof (gfc_char_t));
break;
case EXPR_CONSTANT:
/* Copy target representation, if it exists. */
if (p->representation.string)
{
c = XCNEWVEC (char, p->representation.length + 1);
q->representation.string = c;
memcpy (c, p->representation.string, (p->representation.length + 1));
}
/* Copy the values of any pointer components of p->value. */
switch (q->ts.type)
{
case BT_INTEGER:
mpz_init_set (q->value.integer, p->value.integer);
break;
case BT_REAL:
gfc_set_model_kind (q->ts.kind);
mpfr_init (q->value.real);
mpfr_set (q->value.real, p->value.real, GFC_RND_MODE);
break;
case BT_COMPLEX:
gfc_set_model_kind (q->ts.kind);
mpc_init2 (q->value.complex, mpfr_get_default_prec());
mpc_set (q->value.complex, p->value.complex, GFC_MPC_RND_MODE);
break;
case BT_CHARACTER:
if (p->representation.string)
q->value.character.string
= gfc_char_to_widechar (q->representation.string);
else
{
s = gfc_get_wide_string (p->value.character.length + 1);
q->value.character.string = s;
/* This is the case for the C_NULL_CHAR named constant. */
if (p->value.character.length == 0
&& (p->ts.is_c_interop || p->ts.is_iso_c))
{
*s = '\0';
/* Need to set the length to 1 to make sure the NUL
terminator is copied. */
q->value.character.length = 1;
}
else
memcpy (s, p->value.character.string,
(p->value.character.length + 1) * sizeof (gfc_char_t));
}
break;
case BT_HOLLERITH:
case BT_LOGICAL:
case BT_DERIVED:
case BT_CLASS:
break; /* Already done. */
case BT_PROCEDURE:
case BT_VOID:
/* Should never be reached. */
case BT_UNKNOWN:
gfc_internal_error ("gfc_copy_expr(): Bad expr node");
/* Not reached. */
}
break;
case EXPR_OP:
switch (q->value.op.op)
{
case INTRINSIC_NOT:
case INTRINSIC_PARENTHESES:
case INTRINSIC_UPLUS:
case INTRINSIC_UMINUS:
q->value.op.op1 = gfc_copy_expr (p->value.op.op1);
break;
default: /* Binary operators. */
q->value.op.op1 = gfc_copy_expr (p->value.op.op1);
q->value.op.op2 = gfc_copy_expr (p->value.op.op2);
break;
}
break;
case EXPR_FUNCTION:
q->value.function.actual =
gfc_copy_actual_arglist (p->value.function.actual);
break;
case EXPR_COMPCALL:
case EXPR_PPC:
q->value.compcall.actual =
gfc_copy_actual_arglist (p->value.compcall.actual);
q->value.compcall.tbp = p->value.compcall.tbp;
break;
case EXPR_STRUCTURE:
case EXPR_ARRAY:
q->value.constructor = gfc_constructor_copy (p->value.constructor);
break;
case EXPR_VARIABLE:
case EXPR_NULL:
break;
}
q->shape = gfc_copy_shape (p->shape, p->rank);
q->ref = gfc_copy_ref (p->ref);
return q;
}
/* Workhorse function for gfc_free_expr() that frees everything
beneath an expression node, but not the node itself. This is
useful when we want to simplify a node and replace it with
something else or the expression node belongs to another structure. */
static void
free_expr0 (gfc_expr *e)
{
int n;
switch (e->expr_type)
{
case EXPR_CONSTANT:
/* Free any parts of the value that need freeing. */
switch (e->ts.type)
{
case BT_INTEGER:
mpz_clear (e->value.integer);
break;
case BT_REAL:
mpfr_clear (e->value.real);
break;
case BT_CHARACTER:
free (e->value.character.string);
break;
case BT_COMPLEX:
mpc_clear (e->value.complex);
break;
default:
break;
}
/* Free the representation. */
free (e->representation.string);
break;
case EXPR_OP:
if (e->value.op.op1 != NULL)
gfc_free_expr (e->value.op.op1);
if (e->value.op.op2 != NULL)
gfc_free_expr (e->value.op.op2);
break;
case EXPR_FUNCTION:
gfc_free_actual_arglist (e->value.function.actual);
break;
case EXPR_COMPCALL:
case EXPR_PPC:
gfc_free_actual_arglist (e->value.compcall.actual);
break;
case EXPR_VARIABLE:
break;
case EXPR_ARRAY:
case EXPR_STRUCTURE:
gfc_constructor_free (e->value.constructor);
break;
case EXPR_SUBSTRING:
free (e->value.character.string);
break;
case EXPR_NULL:
break;
default:
gfc_internal_error ("free_expr0(): Bad expr type");
}
/* Free a shape array. */
if (e->shape != NULL)
{
for (n = 0; n < e->rank; n++)
mpz_clear (e->shape[n]);
free (e->shape);
}
gfc_free_ref_list (e->ref);
memset (e, '\0', sizeof (gfc_expr));
}
/* Free an expression node and everything beneath it. */
void
gfc_free_expr (gfc_expr *e)
{
if (e == NULL)
return;
free_expr0 (e);
free (e);
}
/* Free an argument list and everything below it. */
void
gfc_free_actual_arglist (gfc_actual_arglist *a1)
{
gfc_actual_arglist *a2;
while (a1)
{
a2 = a1->next;
gfc_free_expr (a1->expr);
free (a1);
a1 = a2;
}
}
/* Copy an arglist structure and all of the arguments. */
gfc_actual_arglist *
gfc_copy_actual_arglist (gfc_actual_arglist *p)
{
gfc_actual_arglist *head, *tail, *new_arg;
head = tail = NULL;
for (; p; p = p->next)
{
new_arg = gfc_get_actual_arglist ();
*new_arg = *p;
new_arg->expr = gfc_copy_expr (p->expr);
new_arg->next = NULL;
if (head == NULL)
head = new_arg;
else
tail->next = new_arg;
tail = new_arg;
}
return head;
}
/* Free a list of reference structures. */
void
gfc_free_ref_list (gfc_ref *p)
{
gfc_ref *q;
int i;
for (; p; p = q)
{
q = p->next;
switch (p->type)
{
case REF_ARRAY:
for (i = 0; i < GFC_MAX_DIMENSIONS; i++)
{
gfc_free_expr (p->u.ar.start[i]);
gfc_free_expr (p->u.ar.end[i]);
gfc_free_expr (p->u.ar.stride[i]);
}
break;
case REF_SUBSTRING:
gfc_free_expr (p->u.ss.start);
gfc_free_expr (p->u.ss.end);
break;
case REF_COMPONENT:
break;
}
free (p);
}
}
/* Graft the *src expression onto the *dest subexpression. */
void
gfc_replace_expr (gfc_expr *dest, gfc_expr *src)
{
free_expr0 (dest);
*dest = *src;
free (src);
}
/* Try to extract an integer constant from the passed expression node.
Returns an error message or NULL if the result is set. It is
tempting to generate an error and return SUCCESS or FAILURE, but
failure is OK for some callers. */
const char *
gfc_extract_int (gfc_expr *expr, int *result)
{
if (expr->expr_type != EXPR_CONSTANT)
return _("Constant expression required at %C");
if (expr->ts.type != BT_INTEGER)
return _("Integer expression required at %C");
if ((mpz_cmp_si (expr->value.integer, INT_MAX) > 0)
|| (mpz_cmp_si (expr->value.integer, INT_MIN) < 0))
{
return _("Integer value too large in expression at %C");
}
*result = (int) mpz_get_si (expr->value.integer);
return NULL;
}
/* Recursively copy a list of reference structures. */
gfc_ref *
gfc_copy_ref (gfc_ref *src)
{
gfc_array_ref *ar;
gfc_ref *dest;
if (src == NULL)
return NULL;
dest = gfc_get_ref ();
dest->type = src->type;
switch (src->type)
{
case REF_ARRAY:
ar = gfc_copy_array_ref (&src->u.ar);
dest->u.ar = *ar;
free (ar);
break;
case REF_COMPONENT:
dest->u.c = src->u.c;
break;
case REF_SUBSTRING:
dest->u.ss = src->u.ss;
dest->u.ss.start = gfc_copy_expr (src->u.ss.start);
dest->u.ss.end = gfc_copy_expr (src->u.ss.end);
break;
}
dest->next = gfc_copy_ref (src->next);
return dest;
}
/* Detect whether an expression has any vector index array references. */
int
gfc_has_vector_index (gfc_expr *e)
{
gfc_ref *ref;
int i;
for (ref = e->ref; ref; ref = ref->next)
if (ref->type == REF_ARRAY)
for (i = 0; i < ref->u.ar.dimen; i++)
if (ref->u.ar.dimen_type[i] == DIMEN_VECTOR)
return 1;
return 0;
}
/* Copy a shape array. */
mpz_t *
gfc_copy_shape (mpz_t *shape, int rank)
{
mpz_t *new_shape;
int n;
if (shape == NULL)
return NULL;
new_shape = gfc_get_shape (rank);
for (n = 0; n < rank; n++)
mpz_init_set (new_shape[n], shape[n]);
return new_shape;
}
/* Copy a shape array excluding dimension N, where N is an integer
constant expression. Dimensions are numbered in fortran style --
starting with ONE.
So, if the original shape array contains R elements
{ s1 ... sN-1 sN sN+1 ... sR-1 sR}
the result contains R-1 elements:
{ s1 ... sN-1 sN+1 ... sR-1}
If anything goes wrong -- N is not a constant, its value is out
of range -- or anything else, just returns NULL. */
mpz_t *
gfc_copy_shape_excluding (mpz_t *shape, int rank, gfc_expr *dim)
{
mpz_t *new_shape, *s;
int i, n;
if (shape == NULL
|| rank <= 1
|| dim == NULL
|| dim->expr_type != EXPR_CONSTANT
|| dim->ts.type != BT_INTEGER)
return NULL;
n = mpz_get_si (dim->value.integer);
n--; /* Convert to zero based index. */
if (n < 0 || n >= rank)
return NULL;
s = new_shape = gfc_get_shape (rank - 1);
for (i = 0; i < rank; i++)
{
if (i == n)
continue;
mpz_init_set (*s, shape[i]);
s++;
}
return new_shape;
}
/* Return the maximum kind of two expressions. In general, higher
kind numbers mean more precision for numeric types. */
int
gfc_kind_max (gfc_expr *e1, gfc_expr *e2)
{
return (e1->ts.kind > e2->ts.kind) ? e1->ts.kind : e2->ts.kind;
}
/* Returns nonzero if the type is numeric, zero otherwise. */
static int
numeric_type (bt type)
{
return type == BT_COMPLEX || type == BT_REAL || type == BT_INTEGER;
}
/* Returns nonzero if the typespec is a numeric type, zero otherwise. */
int
gfc_numeric_ts (gfc_typespec *ts)
{
return numeric_type (ts->type);
}
/* Return an expression node with an optional argument list attached.
A variable number of gfc_expr pointers are strung together in an
argument list with a NULL pointer terminating the list. */
gfc_expr *
gfc_build_conversion (gfc_expr *e)
{
gfc_expr *p;
p = gfc_get_expr ();
p->expr_type = EXPR_FUNCTION;
p->symtree = NULL;
p->value.function.actual = NULL;
p->value.function.actual = gfc_get_actual_arglist ();
p->value.function.actual->expr = e;
return p;
}
/* Given an expression node with some sort of numeric binary
expression, insert type conversions required to make the operands
have the same type. Conversion warnings are disabled if wconversion
is set to 0.
The exception is that the operands of an exponential don't have to
have the same type. If possible, the base is promoted to the type
of the exponent. For example, 1**2.3 becomes 1.0**2.3, but
1.0**2 stays as it is. */
void
gfc_type_convert_binary (gfc_expr *e, int wconversion)
{
gfc_expr *op1, *op2;
op1 = e->value.op.op1;
op2 = e->value.op.op2;
if (op1->ts.type == BT_UNKNOWN || op2->ts.type == BT_UNKNOWN)
{
gfc_clear_ts (&e->ts);
return;
}
/* Kind conversions of same type. */
if (op1->ts.type == op2->ts.type)
{
if (op1->ts.kind == op2->ts.kind)
{
/* No type conversions. */
e->ts = op1->ts;
goto done;
}
if (op1->ts.kind > op2->ts.kind)
gfc_convert_type_warn (op2, &op1->ts, 2, wconversion);
else
gfc_convert_type_warn (op1, &op2->ts, 2, wconversion);
e->ts = op1->ts;
goto done;
}
/* Integer combined with real or complex. */
if (op2->ts.type == BT_INTEGER)
{
e->ts = op1->ts;
/* Special case for ** operator. */
if (e->value.op.op == INTRINSIC_POWER)
goto done;
gfc_convert_type_warn (e->value.op.op2, &e->ts, 2, wconversion);
goto done;
}
if (op1->ts.type == BT_INTEGER)
{
e->ts = op2->ts;
gfc_convert_type_warn (e->value.op.op1, &e->ts, 2, wconversion);
goto done;
}
/* Real combined with complex. */
e->ts.type = BT_COMPLEX;
if (op1->ts.kind > op2->ts.kind)
e->ts.kind = op1->ts.kind;
else
e->ts.kind = op2->ts.kind;
if (op1->ts.type != BT_COMPLEX || op1->ts.kind != e->ts.kind)
gfc_convert_type_warn (e->value.op.op1, &e->ts, 2, wconversion);
if (op2->ts.type != BT_COMPLEX || op2->ts.kind != e->ts.kind)
gfc_convert_type_warn (e->value.op.op2, &e->ts, 2, wconversion);
done:
return;
}
/* Function to determine if an expression is constant or not. This
function expects that the expression has already been simplified. */
int
gfc_is_constant_expr (gfc_expr *e)
{
gfc_constructor *c;
gfc_actual_arglist *arg;
gfc_symbol *sym;
if (e == NULL)
return 1;
switch (e->expr_type)
{
case EXPR_OP:
return (gfc_is_constant_expr (e->value.op.op1)
&& (e->value.op.op2 == NULL
|| gfc_is_constant_expr (e->value.op.op2)));
case EXPR_VARIABLE:
return 0;
case EXPR_FUNCTION:
case EXPR_PPC:
case EXPR_COMPCALL:
gcc_assert (e->symtree || e->value.function.esym
|| e->value.function.isym);
/* Call to intrinsic with at least one argument. */
if (e->value.function.isym && e->value.function.actual)
{
for (arg = e->value.function.actual; arg; arg = arg->next)
if (!gfc_is_constant_expr (arg->expr))
return 0;
}
/* Specification functions are constant. */
/* F95, 7.1.6.2; F2003, 7.1.7 */
sym = NULL;
if (e->symtree)
sym = e->symtree->n.sym;
if (e->value.function.esym)
sym = e->value.function.esym;
if (sym
&& sym->attr.function
&& sym->attr.pure
&& !sym->attr.intrinsic
&& !sym->attr.recursive
&& sym->attr.proc != PROC_INTERNAL
&& sym->attr.proc != PROC_ST_FUNCTION
&& sym->attr.proc != PROC_UNKNOWN
&& sym->formal == NULL)
return 1;
if (e->value.function.isym
&& (e->value.function.isym->elemental
|| e->value.function.isym->pure
|| e->value.function.isym->inquiry
|| e->value.function.isym->transformational))
return 1;
return 0;
case EXPR_CONSTANT:
case EXPR_NULL:
return 1;
case EXPR_SUBSTRING:
return e->ref == NULL || (gfc_is_constant_expr (e->ref->u.ss.start)
&& gfc_is_constant_expr (e->ref->u.ss.end));
case EXPR_ARRAY:
case EXPR_STRUCTURE:
c = gfc_constructor_first (e->value.constructor);
if ((e->expr_type == EXPR_ARRAY) && c && c->iterator)
return gfc_constant_ac (e);
for (; c; c = gfc_constructor_next (c))
if (!gfc_is_constant_expr (c->expr))
return 0;
return 1;
default:
gfc_internal_error ("gfc_is_constant_expr(): Unknown expression type");
return 0;
}
}
/* Is true if an array reference is followed by a component or substring
reference. */
bool
is_subref_array (gfc_expr * e)
{
gfc_ref * ref;
bool seen_array;
if (e->expr_type != EXPR_VARIABLE)
return false;
if (e->symtree->n.sym->attr.subref_array_pointer)
return true;
seen_array = false;
for (ref = e->ref; ref; ref = ref->next)
{
if (ref->type == REF_ARRAY
&& ref->u.ar.type != AR_ELEMENT)
seen_array = true;
if (seen_array
&& ref->type != REF_ARRAY)
return seen_array;
}
return false;
}
/* Try to collapse intrinsic expressions. */
static gfc_try
simplify_intrinsic_op (gfc_expr *p, int type)
{
gfc_intrinsic_op op;
gfc_expr *op1, *op2, *result;
if (p->value.op.op == INTRINSIC_USER)
return SUCCESS;
op1 = p->value.op.op1;
op2 = p->value.op.op2;
op = p->value.op.op;
if (gfc_simplify_expr (op1, type) == FAILURE)
return FAILURE;
if (gfc_simplify_expr (op2, type) == FAILURE)
return FAILURE;
if (!gfc_is_constant_expr (op1)
|| (op2 != NULL && !gfc_is_constant_expr (op2)))
return SUCCESS;
/* Rip p apart. */
p->value.op.op1 = NULL;
p->value.op.op2 = NULL;
switch (op)
{
case INTRINSIC_PARENTHESES:
result = gfc_parentheses (op1);
break;
case INTRINSIC_UPLUS:
result = gfc_uplus (op1);
break;
case INTRINSIC_UMINUS:
result = gfc_uminus (op1);
break;
case INTRINSIC_PLUS:
result = gfc_add (op1, op2);
break;
case INTRINSIC_MINUS:
result = gfc_subtract (op1, op2);
break;
case INTRINSIC_TIMES:
result = gfc_multiply (op1, op2);
break;
case INTRINSIC_DIVIDE:
result = gfc_divide (op1, op2);
break;
case INTRINSIC_POWER:
result = gfc_power (op1, op2);
break;
case INTRINSIC_CONCAT:
result = gfc_concat (op1, op2);
break;
case INTRINSIC_EQ:
case INTRINSIC_EQ_OS:
result = gfc_eq (op1, op2, op);
break;
case INTRINSIC_NE:
case INTRINSIC_NE_OS:
result = gfc_ne (op1, op2, op);
break;
case INTRINSIC_GT:
case INTRINSIC_GT_OS:
result = gfc_gt (op1, op2, op);
break;
case INTRINSIC_GE:
case INTRINSIC_GE_OS:
result = gfc_ge (op1, op2, op);
break;
case INTRINSIC_LT:
case INTRINSIC_LT_OS:
result = gfc_lt (op1, op2, op);
break;
case INTRINSIC_LE:
case INTRINSIC_LE_OS:
result = gfc_le (op1, op2, op);
break;
case INTRINSIC_NOT:
result = gfc_not (op1);
break;
case INTRINSIC_AND:
result = gfc_and (op1, op2);
break;
case INTRINSIC_OR:
result = gfc_or (op1, op2);
break;
case INTRINSIC_EQV:
result = gfc_eqv (op1, op2);
break;
case INTRINSIC_NEQV:
result = gfc_neqv (op1, op2);
break;
default:
gfc_internal_error ("simplify_intrinsic_op(): Bad operator");
}
if (result == NULL)
{
gfc_free_expr (op1);
gfc_free_expr (op2);
return FAILURE;
}
result->rank = p->rank;
result->where = p->where;
gfc_replace_expr (p, result);
return SUCCESS;
}
/* Subroutine to simplify constructor expressions. Mutually recursive
with gfc_simplify_expr(). */
static gfc_try
simplify_constructor (gfc_constructor_base base, int type)
{
gfc_constructor *c;
gfc_expr *p;
for (c = gfc_constructor_first (base); c; c = gfc_constructor_next (c))
{
if (c->iterator
&& (gfc_simplify_expr (c->iterator->start, type) == FAILURE
|| gfc_simplify_expr (c->iterator->end, type) == FAILURE
|| gfc_simplify_expr (c->iterator->step, type) == FAILURE))
return FAILURE;
if (c->expr)
{
/* Try and simplify a copy. Replace the original if successful
but keep going through the constructor at all costs. Not
doing so can make a dog's dinner of complicated things. */
p = gfc_copy_expr (c->expr);
if (gfc_simplify_expr (p, type) == FAILURE)
{
gfc_free_expr (p);
continue;
}
gfc_replace_expr (c->expr, p);
}
}
return SUCCESS;
}
/* Pull a single array element out of an array constructor. */
static gfc_try
find_array_element (gfc_constructor_base base, gfc_array_ref *ar,
gfc_constructor **rval)
{
unsigned long nelemen;
int i;
mpz_t delta;
mpz_t offset;
mpz_t span;
mpz_t tmp;
gfc_constructor *cons;
gfc_expr *e;
gfc_try t;
t = SUCCESS;
e = NULL;
mpz_init_set_ui (offset, 0);
mpz_init (delta);
mpz_init (tmp);
mpz_init_set_ui (span, 1);
for (i = 0; i < ar->dimen; i++)
{
if (gfc_reduce_init_expr (ar->as->lower[i]) == FAILURE
|| gfc_reduce_init_expr (ar->as->upper[i]) == FAILURE)
{
t = FAILURE;
cons = NULL;
goto depart;
}
e = gfc_copy_expr (ar->start[i]);
if (e->expr_type != EXPR_CONSTANT)
{
cons = NULL;
goto depart;
}
gcc_assert (ar->as->upper[i]->expr_type == EXPR_CONSTANT
&& ar->as->lower[i]->expr_type == EXPR_CONSTANT);
/* Check the bounds. */
if ((ar->as->upper[i]
&& mpz_cmp (e->value.integer,
ar->as->upper[i]->value.integer) > 0)
|| (mpz_cmp (e->value.integer,
ar->as->lower[i]->value.integer) < 0))
{
gfc_error ("Index in dimension %d is out of bounds "
"at %L", i + 1, &ar->c_where[i]);
cons = NULL;
t = FAILURE;
goto depart;
}
mpz_sub (delta, e->value.integer, ar->as->lower[i]->value.integer);
mpz_mul (delta, delta, span);
mpz_add (offset, offset, delta);
mpz_set_ui (tmp, 1);
mpz_add (tmp, tmp, ar->as->upper[i]->value.integer);
mpz_sub (tmp, tmp, ar->as->lower[i]->value.integer);
mpz_mul (span, span, tmp);
}
for (cons = gfc_constructor_first (base), nelemen = mpz_get_ui (offset);
cons && nelemen > 0; cons = gfc_constructor_next (cons), nelemen--)
{
if (cons->iterator)
{
cons = NULL;
goto depart;
}
}
depart:
mpz_clear (delta);
mpz_clear (offset);
mpz_clear (span);
mpz_clear (tmp);
if (e)
gfc_free_expr (e);
*rval = cons;
return t;
}
/* Find a component of a structure constructor. */
static gfc_constructor *
find_component_ref (gfc_constructor_base base, gfc_ref *ref)
{
gfc_component *comp;
gfc_component *pick;
gfc_constructor *c = gfc_constructor_first (base);
comp = ref->u.c.sym->components;
pick = ref->u.c.component;
while (comp != pick)
{
comp = comp->next;
c = gfc_constructor_next (c);
}
return c;
}
/* Replace an expression with the contents of a constructor, removing
the subobject reference in the process. */
static void
remove_subobject_ref (gfc_expr *p, gfc_constructor *cons)
{
gfc_expr *e;
if (cons)
{
e = cons->expr;
cons->expr = NULL;
}
else
e = gfc_copy_expr (p);
e->ref = p->ref->next;
p->ref->next = NULL;
gfc_replace_expr (p, e);
}
/* Pull an array section out of an array constructor. */
static gfc_try
find_array_section (gfc_expr *expr, gfc_ref *ref)
{
int idx;
int rank;
int d;
int shape_i;
int limit;
long unsigned one = 1;
bool incr_ctr;
mpz_t start[GFC_MAX_DIMENSIONS];
mpz_t end[GFC_MAX_DIMENSIONS];
mpz_t stride[GFC_MAX_DIMENSIONS];
mpz_t delta[GFC_MAX_DIMENSIONS];
mpz_t ctr[GFC_MAX_DIMENSIONS];
mpz_t delta_mpz;
mpz_t tmp_mpz;
mpz_t nelts;
mpz_t ptr;
gfc_constructor_base base;
gfc_constructor *cons, *vecsub[GFC_MAX_DIMENSIONS];
gfc_expr *begin;
gfc_expr *finish;
gfc_expr *step;
gfc_expr *upper;
gfc_expr *lower;
gfc_try t;
t = SUCCESS;
base = expr->value.constructor;
expr->value.constructor = NULL;
rank = ref->u.ar.as->rank;
if (expr->shape == NULL)
expr->shape = gfc_get_shape (rank);
mpz_init_set_ui (delta_mpz, one);
mpz_init_set_ui (nelts, one);
mpz_init (tmp_mpz);
/* Do the initialization now, so that we can cleanup without
keeping track of where we were. */
for (d = 0; d < rank; d++)
{
mpz_init (delta[d]);
mpz_init (start[d]);
mpz_init (end[d]);
mpz_init (ctr[d]);
mpz_init (stride[d]);
vecsub[d] = NULL;
}
/* Build the counters to clock through the array reference. */
shape_i = 0;
for (d = 0; d < rank; d++)
{
/* Make this stretch of code easier on the eye! */
begin = ref->u.ar.start[d];
finish = ref->u.ar.end[d];
step = ref->u.ar.stride[d];
lower = ref->u.ar.as->lower[d];
upper = ref->u.ar.as->upper[d];
if (ref->u.ar.dimen_type[d] == DIMEN_VECTOR) /* Vector subscript. */
{
gfc_constructor *ci;
gcc_assert (begin);
if (begin->expr_type != EXPR_ARRAY || !gfc_is_constant_expr (begin))
{
t = FAILURE;
goto cleanup;
}
gcc_assert (begin->rank == 1);
/* Zero-sized arrays have no shape and no elements, stop early. */
if (!begin->shape)
{
mpz_init_set_ui (nelts, 0);
break;
}
vecsub[d] = gfc_constructor_first (begin->value.constructor);
mpz_set (ctr[d], vecsub[d]->expr->value.integer);
mpz_mul (nelts, nelts, begin->shape[0]);
mpz_set (expr->shape[shape_i++], begin->shape[0]);
/* Check bounds. */
for (ci = vecsub[d]; ci; ci = gfc_constructor_next (ci))
{
if (mpz_cmp (ci->expr->value.integer, upper->value.integer) > 0
|| mpz_cmp (ci->expr->value.integer,
lower->value.integer) < 0)
{
gfc_error ("index in dimension %d is out of bounds "
"at %L", d + 1, &ref->u.ar.c_where[d]);
t = FAILURE;
goto cleanup;
}
}
}
else
{
if ((begin && begin->expr_type != EXPR_CONSTANT)
|| (finish && finish->expr_type != EXPR_CONSTANT)
|| (step && step->expr_type != EXPR_CONSTANT))
{
t = FAILURE;
goto cleanup;
}
/* Obtain the stride. */
if (step)
mpz_set (stride[d], step->value.integer);
else
mpz_set_ui (stride[d], one);
if (mpz_cmp_ui (stride[d], 0) == 0)
mpz_set_ui (stride[d], one);
/* Obtain the start value for the index. */
if (begin)
mpz_set (start[d], begin->value.integer);
else
mpz_set (start[d], lower->value.integer);
mpz_set (ctr[d], start[d]);
/* Obtain the end value for the index. */
if (finish)
mpz_set (end[d], finish->value.integer);
else
mpz_set (end[d], upper->value.integer);
/* Separate 'if' because elements sometimes arrive with
non-null end. */
if (ref->u.ar.dimen_type[d] == DIMEN_ELEMENT)
mpz_set (end [d], begin->value.integer);
/* Check the bounds. */
if (mpz_cmp (ctr[d], upper->value.integer) > 0
|| mpz_cmp (end[d], upper->value.integer) > 0
|| mpz_cmp (ctr[d], lower->value.integer) < 0
|| mpz_cmp (end[d], lower->value.integer) < 0)
{
gfc_error ("index in dimension %d is out of bounds "
"at %L", d + 1, &ref->u.ar.c_where[d]);
t = FAILURE;
goto cleanup;
}
/* Calculate the number of elements and the shape. */
mpz_set (tmp_mpz, stride[d]);
mpz_add (tmp_mpz, end[d], tmp_mpz);
mpz_sub (tmp_mpz, tmp_mpz, ctr[d]);
mpz_div (tmp_mpz, tmp_mpz, stride[d]);
mpz_mul (nelts, nelts, tmp_mpz);
/* An element reference reduces the rank of the expression; don't
add anything to the shape array. */
if (ref->u.ar.dimen_type[d] != DIMEN_ELEMENT)
mpz_set (expr->shape[shape_i++], tmp_mpz);
}
/* Calculate the 'stride' (=delta) for conversion of the
counter values into the index along the constructor. */
mpz_set (delta[d], delta_mpz);
mpz_sub (tmp_mpz, upper->value.integer, lower->value.integer);
mpz_add_ui (tmp_mpz, tmp_mpz, one);
mpz_mul (delta_mpz, delta_mpz, tmp_mpz);
}
mpz_init (ptr);
cons = gfc_constructor_first (base);
/* Now clock through the array reference, calculating the index in
the source constructor and transferring the elements to the new
constructor. */
for (idx = 0; idx < (int) mpz_get_si (nelts); idx++)
{
if (ref->u.ar.offset)
mpz_set (ptr, ref->u.ar.offset->value.integer);
else
mpz_init_set_ui (ptr, 0);
incr_ctr = true;
for (d = 0; d < rank; d++)
{
mpz_set (tmp_mpz, ctr[d]);
mpz_sub (tmp_mpz, tmp_mpz, ref->u.ar.as->lower[d]->value.integer);
mpz_mul (tmp_mpz, tmp_mpz, delta[d]);
mpz_add (ptr, ptr, tmp_mpz);
if (!incr_ctr) continue;
if (ref->u.ar.dimen_type[d] == DIMEN_VECTOR) /* Vector subscript. */
{
gcc_assert(vecsub[d]);
if (!gfc_constructor_next (vecsub[d]))
vecsub[d] = gfc_constructor_first (ref->u.ar.start[d]->value.constructor);
else
{
vecsub[d] = gfc_constructor_next (vecsub[d]);
incr_ctr = false;
}
mpz_set (ctr[d], vecsub[d]->expr->value.integer);
}
else
{
mpz_add (ctr[d], ctr[d], stride[d]);
if (mpz_cmp_ui (stride[d], 0) > 0
? mpz_cmp (ctr[d], end[d]) > 0
: mpz_cmp (ctr[d], end[d]) < 0)
mpz_set (ctr[d], start[d]);
else
incr_ctr = false;
}
}
limit = mpz_get_ui (ptr);
if (limit >= gfc_option.flag_max_array_constructor)
{
gfc_error ("The number of elements in the array constructor "
"at %L requires an increase of the allowed %d "
"upper limit. See -fmax-array-constructor "
"option", &expr->where,
gfc_option.flag_max_array_constructor);
return FAILURE;
}
cons = gfc_constructor_lookup (base, limit);
gcc_assert (cons);
gfc_constructor_append_expr (&expr->value.constructor,
gfc_copy_expr (cons->expr), NULL);
}
mpz_clear (ptr);
cleanup:
mpz_clear (delta_mpz);
mpz_clear (tmp_mpz);
mpz_clear (nelts);
for (d = 0; d < rank; d++)
{
mpz_clear (delta[d]);
mpz_clear (start[d]);
mpz_clear (end[d]);
mpz_clear (ctr[d]);
mpz_clear (stride[d]);
}
gfc_constructor_free (base);
return t;
}
/* Pull a substring out of an expression. */
static gfc_try
find_substring_ref (gfc_expr *p, gfc_expr **newp)
{
int end;
int start;
int length;
gfc_char_t *chr;
if (p->ref->u.ss.start->expr_type != EXPR_CONSTANT
|| p->ref->u.ss.end->expr_type != EXPR_CONSTANT)
return FAILURE;
*newp = gfc_copy_expr (p);
free ((*newp)->value.character.string);
end = (int) mpz_get_ui (p->ref->u.ss.end->value.integer);
start = (int) mpz_get_ui (p->ref->u.ss.start->value.integer);
length = end - start + 1;
chr = (*newp)->value.character.string = gfc_get_wide_string (length + 1);
(*newp)->value.character.length = length;
memcpy (chr, &p->value.character.string[start - 1],
length * sizeof (gfc_char_t));
chr[length] = '\0';
return SUCCESS;
}
/* Simplify a subobject reference of a constructor. This occurs when
parameter variable values are substituted. */
static gfc_try
simplify_const_ref (gfc_expr *p)
{
gfc_constructor *cons, *c;
gfc_expr *newp;
gfc_ref *last_ref;
while (p->ref)
{
switch (p->ref->type)
{
case REF_ARRAY:
switch (p->ref->u.ar.type)
{
case AR_ELEMENT:
/* , parameter :: x() = scalar_expr
will generate this. */
if (p->expr_type != EXPR_ARRAY)
{
remove_subobject_ref (p, NULL);
break;
}
if (find_array_element (p->value.constructor, &p->ref->u.ar,
&cons) == FAILURE)
return FAILURE;
if (!cons)
return SUCCESS;
remove_subobject_ref (p, cons);
break;
case AR_SECTION:
if (find_array_section (p, p->ref) == FAILURE)
return FAILURE;
p->ref->u.ar.type = AR_FULL;
/* Fall through. */
case AR_FULL:
if (p->ref->next != NULL
&& (p->ts.type == BT_CHARACTER || p->ts.type == BT_DERIVED))
{
for (c = gfc_constructor_first (p->value.constructor);
c; c = gfc_constructor_next (c))
{
c->expr->ref = gfc_copy_ref (p->ref->next);
if (simplify_const_ref (c->expr) == FAILURE)
return FAILURE;
}
if (p->ts.type == BT_DERIVED
&& p->ref->next
&& (c = gfc_constructor_first (p->value.constructor)))
{
/* There may have been component references. */
p->ts = c->expr->ts;
}
last_ref = p->ref;
for (; last_ref->next; last_ref = last_ref->next) {};
if (p->ts.type == BT_CHARACTER
&& last_ref->type == REF_SUBSTRING)
{
/* If this is a CHARACTER array and we possibly took
a substring out of it, update the type-spec's
character length according to the first element
(as all should have the same length). */
int string_len;
if ((c = gfc_constructor_first (p->value.constructor)))
{
const gfc_expr* first = c->expr;
gcc_assert (first->expr_type == EXPR_CONSTANT);
gcc_assert (first->ts.type == BT_CHARACTER);
string_len = first->value.character.length;
}
else
string_len = 0;
if (!p->ts.u.cl)
p->ts.u.cl = gfc_new_charlen (p->symtree->n.sym->ns,
NULL);
else
gfc_free_expr (p->ts.u.cl->length);
p->ts.u.cl->length
= gfc_get_int_expr (gfc_default_integer_kind,
NULL, string_len);
}
}
gfc_free_ref_list (p->ref);
p->ref = NULL;
break;
default:
return SUCCESS;
}
break;
case REF_COMPONENT:
cons = find_component_ref (p->value.constructor, p->ref);
remove_subobject_ref (p, cons);
break;
case REF_SUBSTRING:
if (find_substring_ref (p, &newp) == FAILURE)
return FAILURE;
gfc_replace_expr (p, newp);
gfc_free_ref_list (p->ref);
p->ref = NULL;
break;
}
}
return SUCCESS;
}
/* Simplify a chain of references. */
static gfc_try
simplify_ref_chain (gfc_ref *ref, int type)
{
int n;
for (; ref; ref = ref->next)
{
switch (ref->type)
{
case REF_ARRAY:
for (n = 0; n < ref->u.ar.dimen; n++)
{
if (gfc_simplify_expr (ref->u.ar.start[n], type) == FAILURE)
return FAILURE;
if (gfc_simplify_expr (ref->u.ar.end[n], type) == FAILURE)
return FAILURE;
if (gfc_simplify_expr (ref->u.ar.stride[n], type) == FAILURE)
return FAILURE;
}
break;
case REF_SUBSTRING:
if (gfc_simplify_expr (ref->u.ss.start, type) == FAILURE)
return FAILURE;
if (gfc_simplify_expr (ref->u.ss.end, type) == FAILURE)
return FAILURE;
break;
default:
break;
}
}
return SUCCESS;
}
/* Try to substitute the value of a parameter variable. */
static gfc_try
simplify_parameter_variable (gfc_expr *p, int type)
{
gfc_expr *e;
gfc_try t;
e = gfc_copy_expr (p->symtree->n.sym->value);
if (e == NULL)
return FAILURE;
e->rank = p->rank;
/* Do not copy subobject refs for constant. */
if (e->expr_type != EXPR_CONSTANT && p->ref != NULL)
e->ref = gfc_copy_ref (p->ref);
t = gfc_simplify_expr (e, type);
/* Only use the simplification if it eliminated all subobject references. */
if (t == SUCCESS && !e->ref)
gfc_replace_expr (p, e);
else
gfc_free_expr (e);
return t;
}
/* Given an expression, simplify it by collapsing constant
expressions. Most simplification takes place when the expression
tree is being constructed. If an intrinsic function is simplified
at some point, we get called again to collapse the result against
other constants.
We work by recursively simplifying expression nodes, simplifying
intrinsic functions where possible, which can lead to further
constant collapsing. If an operator has constant operand(s), we
rip the expression apart, and rebuild it, hoping that it becomes
something simpler.
The expression type is defined for:
0 Basic expression parsing
1 Simplifying array constructors -- will substitute
iterator values.
Returns FAILURE on error, SUCCESS otherwise.
NOTE: Will return SUCCESS even if the expression can not be simplified. */
gfc_try
gfc_simplify_expr (gfc_expr *p, int type)
{
gfc_actual_arglist *ap;
if (p == NULL)
return SUCCESS;
switch (p->expr_type)
{
case EXPR_CONSTANT:
case EXPR_NULL:
break;
case EXPR_FUNCTION:
for (ap = p->value.function.actual; ap; ap = ap->next)
if (gfc_simplify_expr (ap->expr, type) == FAILURE)
return FAILURE;
if (p->value.function.isym != NULL
&& gfc_intrinsic_func_interface (p, 1) == MATCH_ERROR)
return FAILURE;
break;
case EXPR_SUBSTRING:
if (simplify_ref_chain (p->ref, type) == FAILURE)
return FAILURE;
if (gfc_is_constant_expr (p))
{
gfc_char_t *s;
int start, end;
start = 0;
if (p->ref && p->ref->u.ss.start)
{
gfc_extract_int (p->ref->u.ss.start, &start);
start--; /* Convert from one-based to zero-based. */
}
end = p->value.character.length;
if (p->ref && p->ref->u.ss.end)
gfc_extract_int (p->ref->u.ss.end, &end);
s = gfc_get_wide_string (end - start + 2);
memcpy (s, p->value.character.string + start,
(end - start) * sizeof (gfc_char_t));
s[end - start + 1] = '\0'; /* TODO: C-style string. */
free (p->value.character.string);
p->value.character.string = s;
p->value.character.length = end - start;
p->ts.u.cl = gfc_new_charlen (gfc_current_ns, NULL);
p->ts.u.cl->length = gfc_get_int_expr (gfc_default_integer_kind,
NULL,
p->value.character.length);
gfc_free_ref_list (p->ref);
p->ref = NULL;
p->expr_type = EXPR_CONSTANT;
}
break;
case EXPR_OP:
if (simplify_intrinsic_op (p, type) == FAILURE)
return FAILURE;
break;
case EXPR_VARIABLE:
/* Only substitute array parameter variables if we are in an
initialization expression, or we want a subsection. */
if (p->symtree->n.sym->attr.flavor == FL_PARAMETER
&& (gfc_init_expr_flag || p->ref
|| p->symtree->n.sym->value->expr_type != EXPR_ARRAY))
{
if (simplify_parameter_variable (p, type) == FAILURE)
return FAILURE;
break;
}
if (type == 1)
{
gfc_simplify_iterator_var (p);
}
/* Simplify subcomponent references. */
if (simplify_ref_chain (p->ref, type) == FAILURE)
return FAILURE;
break;
case EXPR_STRUCTURE:
case EXPR_ARRAY:
if (simplify_ref_chain (p->ref, type) == FAILURE)
return FAILURE;
if (simplify_constructor (p->value.constructor, type) == FAILURE)
return FAILURE;
if (p->expr_type == EXPR_ARRAY && p->ref && p->ref->type == REF_ARRAY
&& p->ref->u.ar.type == AR_FULL)
gfc_expand_constructor (p, false);
if (simplify_const_ref (p) == FAILURE)
return FAILURE;
break;
case EXPR_COMPCALL:
case EXPR_PPC:
gcc_unreachable ();
break;
}
return SUCCESS;
}
/* Returns the type of an expression with the exception that iterator
variables are automatically integers no matter what else they may
be declared as. */
static bt
et0 (gfc_expr *e)
{
if (e->expr_type == EXPR_VARIABLE && gfc_check_iter_variable (e) == SUCCESS)
return BT_INTEGER;
return e->ts.type;
}
/* Check an intrinsic arithmetic operation to see if it is consistent
with some type of expression. */
static gfc_try check_init_expr (gfc_expr *);
/* Scalarize an expression for an elemental intrinsic call. */
static gfc_try
scalarize_intrinsic_call (gfc_expr *e)
{
gfc_actual_arglist *a, *b;
gfc_constructor_base ctor;
gfc_constructor *args[5];
gfc_constructor *ci, *new_ctor;
gfc_expr *expr, *old;
int n, i, rank[5], array_arg;
/* Find which, if any, arguments are arrays. Assume that the old
expression carries the type information and that the first arg
that is an array expression carries all the shape information.*/
n = array_arg = 0;
a = e->value.function.actual;
for (; a; a = a->next)
{
n++;
if (a->expr->expr_type != EXPR_ARRAY)
continue;
array_arg = n;
expr = gfc_copy_expr (a->expr);
break;
}
if (!array_arg)
return FAILURE;
old = gfc_copy_expr (e);
gfc_constructor_free (expr->value.constructor);
expr->value.constructor = NULL;
expr->ts = old->ts;
expr->where = old->where;
expr->expr_type = EXPR_ARRAY;
/* Copy the array argument constructors into an array, with nulls
for the scalars. */
n = 0;
a = old->value.function.actual;
for (; a; a = a->next)
{
/* Check that this is OK for an initialization expression. */
if (a->expr && check_init_expr (a->expr) == FAILURE)
goto cleanup;
rank[n] = 0;
if (a->expr && a->expr->rank && a->expr->expr_type == EXPR_VARIABLE)
{
rank[n] = a->expr->rank;
ctor = a->expr->symtree->n.sym->value->value.constructor;
args[n] = gfc_constructor_first (ctor);
}
else if (a->expr && a->expr->expr_type == EXPR_ARRAY)
{
if (a->expr->rank)
rank[n] = a->expr->rank;
else
rank[n] = 1;
ctor = gfc_constructor_copy (a->expr->value.constructor);
args[n] = gfc_constructor_first (ctor);
}
else
args[n] = NULL;
n++;
}
/* Using the array argument as the master, step through the array
calling the function for each element and advancing the array
constructors together. */
for (ci = args[array_arg - 1]; ci; ci = gfc_constructor_next (ci))
{
new_ctor = gfc_constructor_append_expr (&expr->value.constructor,
gfc_copy_expr (old), NULL);
gfc_free_actual_arglist (new_ctor->expr->value.function.actual);
a = NULL;
b = old->value.function.actual;
for (i = 0; i < n; i++)
{
if (a == NULL)
new_ctor->expr->value.function.actual
= a = gfc_get_actual_arglist ();
else
{
a->next = gfc_get_actual_arglist ();
a = a->next;
}
if (args[i])
a->expr = gfc_copy_expr (args[i]->expr);
else
a->expr = gfc_copy_expr (b->expr);
b = b->next;
}
/* Simplify the function calls. If the simplification fails, the
error will be flagged up down-stream or the library will deal
with it. */
gfc_simplify_expr (new_ctor->expr, 0);
for (i = 0; i < n; i++)
if (args[i])
args[i] = gfc_constructor_next (args[i]);
for (i = 1; i < n; i++)
if (rank[i] && ((args[i] != NULL && args[array_arg - 1] == NULL)
|| (args[i] == NULL && args[array_arg - 1] != NULL)))
goto compliance;
}
free_expr0 (e);
*e = *expr;
gfc_free_expr (old);
return SUCCESS;
compliance:
gfc_error_now ("elemental function arguments at %C are not compliant");
cleanup:
gfc_free_expr (expr);
gfc_free_expr (old);
return FAILURE;
}
static gfc_try
check_intrinsic_op (gfc_expr *e, gfc_try (*check_function) (gfc_expr *))
{
gfc_expr *op1 = e->value.op.op1;
gfc_expr *op2 = e->value.op.op2;
if ((*check_function) (op1) == FAILURE)
return FAILURE;
switch (e->value.op.op)
{
case INTRINSIC_UPLUS:
case INTRINSIC_UMINUS:
if (!numeric_type (et0 (op1)))
goto not_numeric;
break;
case INTRINSIC_EQ:
case INTRINSIC_EQ_OS:
case INTRINSIC_NE:
case INTRINSIC_NE_OS:
case INTRINSIC_GT:
case INTRINSIC_GT_OS:
case INTRINSIC_GE:
case INTRINSIC_GE_OS:
case INTRINSIC_LT:
case INTRINSIC_LT_OS:
case INTRINSIC_LE:
case INTRINSIC_LE_OS:
if ((*check_function) (op2) == FAILURE)
return FAILURE;
if (!(et0 (op1) == BT_CHARACTER && et0 (op2) == BT_CHARACTER)
&& !(numeric_type (et0 (op1)) && numeric_type (et0 (op2))))
{
gfc_error ("Numeric or CHARACTER operands are required in "
"expression at %L", &e->where);
return FAILURE;
}
break;
case INTRINSIC_PLUS:
case INTRINSIC_MINUS:
case INTRINSIC_TIMES:
case INTRINSIC_DIVIDE:
case INTRINSIC_POWER:
if ((*check_function) (op2) == FAILURE)
return FAILURE;
if (!numeric_type (et0 (op1)) || !numeric_type (et0 (op2)))
goto not_numeric;
break;
case INTRINSIC_CONCAT:
if ((*check_function) (op2) == FAILURE)
return FAILURE;
if (et0 (op1) != BT_CHARACTER || et0 (op2) != BT_CHARACTER)
{
gfc_error ("Concatenation operator in expression at %L "
"must have two CHARACTER operands", &op1->where);
return FAILURE;
}
if (op1->ts.kind != op2->ts.kind)
{
gfc_error ("Concat operator at %L must concatenate strings of the "
"same kind", &e->where);
return FAILURE;
}
break;
case INTRINSIC_NOT:
if (et0 (op1) != BT_LOGICAL)
{
gfc_error (".NOT. operator in expression at %L must have a LOGICAL "
"operand", &op1->where);
return FAILURE;
}
break;
case INTRINSIC_AND:
case INTRINSIC_OR:
case INTRINSIC_EQV:
case INTRINSIC_NEQV:
if ((*check_function) (op2) == FAILURE)
return FAILURE;
if (et0 (op1) != BT_LOGICAL || et0 (op2) != BT_LOGICAL)
{
gfc_error ("LOGICAL operands are required in expression at %L",
&e->where);
return FAILURE;
}
break;
case INTRINSIC_PARENTHESES:
break;
default:
gfc_error ("Only intrinsic operators can be used in expression at %L",
&e->where);
return FAILURE;
}
return SUCCESS;
not_numeric:
gfc_error ("Numeric operands are required in expression at %L", &e->where);
return FAILURE;
}
/* F2003, 7.1.7 (3): In init expression, allocatable components
must not be data-initialized. */
static gfc_try
check_alloc_comp_init (gfc_expr *e)
{
gfc_component *comp;
gfc_constructor *ctor;
gcc_assert (e->expr_type == EXPR_STRUCTURE);
gcc_assert (e->ts.type == BT_DERIVED);
for (comp = e->ts.u.derived->components,
ctor = gfc_constructor_first (e->value.constructor);
comp; comp = comp->next, ctor = gfc_constructor_next (ctor))
{
if (comp->attr.allocatable
&& ctor->expr->expr_type != EXPR_NULL)
{
gfc_error("Invalid initialization expression for ALLOCATABLE "
"component '%s' in structure constructor at %L",
comp->name, &ctor->expr->where);
return FAILURE;
}
}
return SUCCESS;
}
static match
check_init_expr_arguments (gfc_expr *e)
{
gfc_actual_arglist *ap;
for (ap = e->value.function.actual; ap; ap = ap->next)
if (check_init_expr (ap->expr) == FAILURE)
return MATCH_ERROR;
return MATCH_YES;
}
static gfc_try check_restricted (gfc_expr *);
/* F95, 7.1.6.1, Initialization expressions, (7)
F2003, 7.1.7 Initialization expression, (8) */
static match
check_inquiry (gfc_expr *e, int not_restricted)
{
const char *name;
const char *const *functions;
static const char *const inquiry_func_f95[] = {
"lbound", "shape", "size", "ubound",
"bit_size", "len", "kind",
"digits", "epsilon", "huge", "maxexponent", "minexponent",
"precision", "radix", "range", "tiny",
NULL
};
static const char *const inquiry_func_f2003[] = {
"lbound", "shape", "size", "ubound",
"bit_size", "len", "kind",
"digits", "epsilon", "huge", "maxexponent", "minexponent",
"precision", "radix", "range", "tiny",
"new_line", NULL
};
int i;
gfc_actual_arglist *ap;
if (!e->value.function.isym
|| !e->value.function.isym->inquiry)
return MATCH_NO;
/* An undeclared parameter will get us here (PR25018). */
if (e->symtree == NULL)
return MATCH_NO;
name = e->symtree->n.sym->name;
functions = (gfc_option.warn_std & GFC_STD_F2003)
? inquiry_func_f2003 : inquiry_func_f95;
for (i = 0; functions[i]; i++)
if (strcmp (functions[i], name) == 0)
break;
if (functions[i] == NULL)
return MATCH_ERROR;
/* At this point we have an inquiry function with a variable argument. The
type of the variable might be undefined, but we need it now, because the
arguments of these functions are not allowed to be undefined. */
for (ap = e->value.function.actual; ap; ap = ap->next)
{
if (!ap->expr)
continue;
if (ap->expr->ts.type == BT_UNKNOWN)
{
if (ap->expr->symtree->n.sym->ts.type == BT_UNKNOWN
&& gfc_set_default_type (ap->expr->symtree->n.sym, 0, gfc_current_ns)
== FAILURE)
return MATCH_NO;
ap->expr->ts = ap->expr->symtree->n.sym->ts;
}
/* Assumed character length will not reduce to a constant expression
with LEN, as required by the standard. */
if (i == 5 && not_restricted
&& ap->expr->symtree->n.sym->ts.type == BT_CHARACTER
&& (ap->expr->symtree->n.sym->ts.u.cl->length == NULL
|| ap->expr->symtree->n.sym->ts.deferred))
{
gfc_error ("Assumed or deferred character length variable '%s' "
" in constant expression at %L",
ap->expr->symtree->n.sym->name,
&ap->expr->where);
return MATCH_ERROR;
}
else if (not_restricted && check_init_expr (ap->expr) == FAILURE)
return MATCH_ERROR;
if (not_restricted == 0
&& ap->expr->expr_type != EXPR_VARIABLE
&& check_restricted (ap->expr) == FAILURE)
return MATCH_ERROR;
if (not_restricted == 0
&& ap->expr->expr_type == EXPR_VARIABLE
&& ap->expr->symtree->n.sym->attr.dummy
&& ap->expr->symtree->n.sym->attr.optional)
return MATCH_NO;
}
return MATCH_YES;
}
/* F95, 7.1.6.1, Initialization expressions, (5)
F2003, 7.1.7 Initialization expression, (5) */
static match
check_transformational (gfc_expr *e)
{
static const char * const trans_func_f95[] = {
"repeat", "reshape", "selected_int_kind",
"selected_real_kind", "transfer", "trim", NULL
};
static const char * const trans_func_f2003[] = {
"all", "any", "count", "dot_product", "matmul", "null", "pack",
"product", "repeat", "reshape", "selected_char_kind", "selected_int_kind",
"selected_real_kind", "spread", "sum", "transfer", "transpose",
"trim", "unpack", NULL
};
int i;
const char *name;
const char *const *functions;
if (!e->value.function.isym
|| !e->value.function.isym->transformational)
return MATCH_NO;
name = e->symtree->n.sym->name;
functions = (gfc_option.allow_std & GFC_STD_F2003)
? trans_func_f2003 : trans_func_f95;
/* NULL() is dealt with below. */
if (strcmp ("null", name) == 0)
return MATCH_NO;
for (i = 0; functions[i]; i++)
if (strcmp (functions[i], name) == 0)
break;
if (functions[i] == NULL)
{
gfc_error("transformational intrinsic '%s' at %L is not permitted "
"in an initialization expression", name, &e->where);
return MATCH_ERROR;
}
return check_init_expr_arguments (e);
}
/* F95, 7.1.6.1, Initialization expressions, (6)
F2003, 7.1.7 Initialization expression, (6) */
static match
check_null (gfc_expr *e)
{
if (strcmp ("null", e->symtree->n.sym->name) != 0)
return MATCH_NO;
return check_init_expr_arguments (e);
}
static match
check_elemental (gfc_expr *e)
{
if (!e->value.function.isym
|| !e->value.function.isym->elemental)
return MATCH_NO;
if (e->ts.type != BT_INTEGER
&& e->ts.type != BT_CHARACTER
&& gfc_notify_std (GFC_STD_F2003, "Extension: Evaluation of "
"nonstandard initialization expression at %L",
&e->where) == FAILURE)
return MATCH_ERROR;
return check_init_expr_arguments (e);
}
static match
check_conversion (gfc_expr *e)
{
if (!e->value.function.isym
|| !e->value.function.isym->conversion)
return MATCH_NO;
return check_init_expr_arguments (e);
}
/* Verify that an expression is an initialization expression. A side
effect is that the expression tree is reduced to a single constant
node if all goes well. This would normally happen when the
expression is constructed but function references are assumed to be
intrinsics in the context of initialization expressions. If
FAILURE is returned an error message has been generated. */
static gfc_try
check_init_expr (gfc_expr *e)
{
match m;
gfc_try t;
if (e == NULL)
return SUCCESS;
switch (e->expr_type)
{
case EXPR_OP:
t = check_intrinsic_op (e, check_init_expr);
if (t == SUCCESS)
t = gfc_simplify_expr (e, 0);
break;
case EXPR_FUNCTION:
t = FAILURE;
{
gfc_intrinsic_sym* isym;
gfc_symbol* sym;
sym = e->symtree->n.sym;
if (!gfc_is_intrinsic (sym, 0, e->where)
|| (m = gfc_intrinsic_func_interface (e, 0)) != MATCH_YES)
{
gfc_error ("Function '%s' in initialization expression at %L "
"must be an intrinsic function",
e->symtree->n.sym->name, &e->where);
break;
}
if ((m = check_conversion (e)) == MATCH_NO
&& (m = check_inquiry (e, 1)) == MATCH_NO
&& (m = check_null (e)) == MATCH_NO
&& (m = check_transformational (e)) == MATCH_NO
&& (m = check_elemental (e)) == MATCH_NO)
{
gfc_error ("Intrinsic function '%s' at %L is not permitted "
"in an initialization expression",
e->symtree->n.sym->name, &e->where);
m = MATCH_ERROR;
}
/* Try to scalarize an elemental intrinsic function that has an
array argument. */
isym = gfc_find_function (e->symtree->n.sym->name);
if (isym && isym->elemental
&& (t = scalarize_intrinsic_call (e)) == SUCCESS)
break;
}
if (m == MATCH_YES)
t = gfc_simplify_expr (e, 0);
break;
case EXPR_VARIABLE:
t = SUCCESS;
if (gfc_check_iter_variable (e) == SUCCESS)
break;
if (e->symtree->n.sym->attr.flavor == FL_PARAMETER)
{
/* A PARAMETER shall not be used to define itself, i.e.
REAL, PARAMETER :: x = transfer(0, x)
is invalid. */
if (!e->symtree->n.sym->value)
{
gfc_error("PARAMETER '%s' is used at %L before its definition "
"is complete", e->symtree->n.sym->name, &e->where);
t = FAILURE;
}
else
t = simplify_parameter_variable (e, 0);
break;
}
if (gfc_in_match_data ())
break;
t = FAILURE;
if (e->symtree->n.sym->as)
{
switch (e->symtree->n.sym->as->type)
{
case AS_ASSUMED_SIZE:
gfc_error ("Assumed size array '%s' at %L is not permitted "
"in an initialization expression",
e->symtree->n.sym->name, &e->where);
break;
case AS_ASSUMED_SHAPE:
gfc_error ("Assumed shape array '%s' at %L is not permitted "
"in an initialization expression",
e->symtree->n.sym->name, &e->where);
break;
case AS_DEFERRED:
gfc_error ("Deferred array '%s' at %L is not permitted "
"in an initialization expression",
e->symtree->n.sym->name, &e->where);
break;
case AS_EXPLICIT:
gfc_error ("Array '%s' at %L is a variable, which does "
"not reduce to a constant expression",
e->symtree->n.sym->name, &e->where);
break;
default:
gcc_unreachable();
}
}
else
gfc_error ("Parameter '%s' at %L has not been declared or is "
"a variable, which does not reduce to a constant "
"expression", e->symtree->n.sym->name, &e->where);
break;
case EXPR_CONSTANT:
case EXPR_NULL:
t = SUCCESS;
break;
case EXPR_SUBSTRING:
t = check_init_expr (e->ref->u.ss.start);
if (t == FAILURE)
break;
t = check_init_expr (e->ref->u.ss.end);
if (t == SUCCESS)
t = gfc_simplify_expr (e, 0);
break;
case EXPR_STRUCTURE:
t = e->ts.is_iso_c ? SUCCESS : FAILURE;
if (t == SUCCESS)
break;
t = check_alloc_comp_init (e);
if (t == FAILURE)
break;
t = gfc_check_constructor (e, check_init_expr);
if (t == FAILURE)
break;
break;
case EXPR_ARRAY:
t = gfc_check_constructor (e, check_init_expr);
if (t == FAILURE)
break;
t = gfc_expand_constructor (e, true);
if (t == FAILURE)
break;
t = gfc_check_constructor_type (e);
break;
default:
gfc_internal_error ("check_init_expr(): Unknown expression type");
}
return t;
}
/* Reduces a general expression to an initialization expression (a constant).
This used to be part of gfc_match_init_expr.
Note that this function doesn't free the given expression on FAILURE. */
gfc_try
gfc_reduce_init_expr (gfc_expr *expr)
{
gfc_try t;
gfc_init_expr_flag = true;
t = gfc_resolve_expr (expr);
if (t == SUCCESS)
t = check_init_expr (expr);
gfc_init_expr_flag = false;
if (t == FAILURE)
return FAILURE;
if (expr->expr_type == EXPR_ARRAY)
{
if (gfc_check_constructor_type (expr) == FAILURE)
return FAILURE;
if (gfc_expand_constructor (expr, true) == FAILURE)
return FAILURE;
}
return SUCCESS;
}
/* Match an initialization expression. We work by first matching an
expression, then reducing it to a constant. */
match
gfc_match_init_expr (gfc_expr **result)
{
gfc_expr *expr;
match m;
gfc_try t;
expr = NULL;
gfc_init_expr_flag = true;
m = gfc_match_expr (&expr);
if (m != MATCH_YES)
{
gfc_init_expr_flag = false;
return m;
}
t = gfc_reduce_init_expr (expr);
if (t != SUCCESS)
{
gfc_free_expr (expr);
gfc_init_expr_flag = false;
return MATCH_ERROR;
}
*result = expr;
gfc_init_expr_flag = false;
return MATCH_YES;
}
/* Given an actual argument list, test to see that each argument is a
restricted expression and optionally if the expression type is
integer or character. */
static gfc_try
restricted_args (gfc_actual_arglist *a)
{
for (; a; a = a->next)
{
if (check_restricted (a->expr) == FAILURE)
return FAILURE;
}
return SUCCESS;
}
/************* Restricted/specification expressions *************/
/* Make sure a non-intrinsic function is a specification function. */
static gfc_try
external_spec_function (gfc_expr *e)
{
gfc_symbol *f;
f = e->value.function.esym;
if (f->attr.proc == PROC_ST_FUNCTION)
{
gfc_error ("Specification function '%s' at %L cannot be a statement "
"function", f->name, &e->where);
return FAILURE;
}
if (f->attr.proc == PROC_INTERNAL)
{
gfc_error ("Specification function '%s' at %L cannot be an internal "
"function", f->name, &e->where);
return FAILURE;
}
if (!f->attr.pure && !f->attr.elemental)
{
gfc_error ("Specification function '%s' at %L must be PURE", f->name,
&e->where);
return FAILURE;
}
if (f->attr.recursive)
{
gfc_error ("Specification function '%s' at %L cannot be RECURSIVE",
f->name, &e->where);
return FAILURE;
}
return restricted_args (e->value.function.actual);
}
/* Check to see that a function reference to an intrinsic is a
restricted expression. */
static gfc_try
restricted_intrinsic (gfc_expr *e)
{
/* TODO: Check constraints on inquiry functions. 7.1.6.2 (7). */
if (check_inquiry (e, 0) == MATCH_YES)
return SUCCESS;
return restricted_args (e->value.function.actual);
}
/* Check the expressions of an actual arglist. Used by check_restricted. */
static gfc_try
check_arglist (gfc_actual_arglist* arg, gfc_try (*checker) (gfc_expr*))
{
for (; arg; arg = arg->next)
if (checker (arg->expr) == FAILURE)
return FAILURE;
return SUCCESS;
}
/* Check the subscription expressions of a reference chain with a checking
function; used by check_restricted. */
static gfc_try
check_references (gfc_ref* ref, gfc_try (*checker) (gfc_expr*))
{
int dim;
if (!ref)
return SUCCESS;
switch (ref->type)
{
case REF_ARRAY:
for (dim = 0; dim != ref->u.ar.dimen; ++dim)
{
if (checker (ref->u.ar.start[dim]) == FAILURE)
return FAILURE;
if (checker (ref->u.ar.end[dim]) == FAILURE)
return FAILURE;
if (checker (ref->u.ar.stride[dim]) == FAILURE)
return FAILURE;
}
break;
case REF_COMPONENT:
/* Nothing needed, just proceed to next reference. */
break;
case REF_SUBSTRING:
if (checker (ref->u.ss.start) == FAILURE)
return FAILURE;
if (checker (ref->u.ss.end) == FAILURE)
return FAILURE;
break;
default:
gcc_unreachable ();
break;
}
return check_references (ref->next, checker);
}
/* Verify that an expression is a restricted expression. Like its
cousin check_init_expr(), an error message is generated if we
return FAILURE. */
static gfc_try
check_restricted (gfc_expr *e)
{
gfc_symbol* sym;
gfc_try t;
if (e == NULL)
return SUCCESS;
switch (e->expr_type)
{
case EXPR_OP:
t = check_intrinsic_op (e, check_restricted);
if (t == SUCCESS)
t = gfc_simplify_expr (e, 0);
break;
case EXPR_FUNCTION:
if (e->value.function.esym)
{
t = check_arglist (e->value.function.actual, &check_restricted);
if (t == SUCCESS)
t = external_spec_function (e);
}
else
{
if (e->value.function.isym && e->value.function.isym->inquiry)
t = SUCCESS;
else
t = check_arglist (e->value.function.actual, &check_restricted);
if (t == SUCCESS)
t = restricted_intrinsic (e);
}
break;
case EXPR_VARIABLE:
sym = e->symtree->n.sym;
t = FAILURE;
/* If a dummy argument appears in a context that is valid for a
restricted expression in an elemental procedure, it will have
already been simplified away once we get here. Therefore we
don't need to jump through hoops to distinguish valid from
invalid cases. */
if (sym->attr.dummy && sym->ns == gfc_current_ns
&& sym->ns->proc_name && sym->ns->proc_name->attr.elemental)
{
gfc_error ("Dummy argument '%s' not allowed in expression at %L",
sym->name, &e->where);
break;
}
if (sym->attr.optional)
{
gfc_error ("Dummy argument '%s' at %L cannot be OPTIONAL",
sym->name, &e->where);
break;
}
if (sym->attr.intent == INTENT_OUT)
{
gfc_error ("Dummy argument '%s' at %L cannot be INTENT(OUT)",
sym->name, &e->where);
break;
}
/* Check reference chain if any. */
if (check_references (e->ref, &check_restricted) == FAILURE)
break;
/* gfc_is_formal_arg broadcasts that a formal argument list is being
processed in resolve.c(resolve_formal_arglist). This is done so
that host associated dummy array indices are accepted (PR23446).
This mechanism also does the same for the specification expressions
of array-valued functions. */
if (e->error
|| sym->attr.in_common
|| sym->attr.use_assoc
|| sym->attr.dummy
|| sym->attr.implied_index
|| sym->attr.flavor == FL_PARAMETER
|| (sym->ns && sym->ns == gfc_current_ns->parent)
|| (sym->ns && gfc_current_ns->parent
&& sym->ns == gfc_current_ns->parent->parent)
|| (sym->ns->proc_name != NULL
&& sym->ns->proc_name->attr.flavor == FL_MODULE)
|| (gfc_is_formal_arg () && (sym->ns == gfc_current_ns)))
{
t = SUCCESS;
break;
}
gfc_error ("Variable '%s' cannot appear in the expression at %L",
sym->name, &e->where);
/* Prevent a repetition of the error. */
e->error = 1;
break;
case EXPR_NULL:
case EXPR_CONSTANT:
t = SUCCESS;
break;
case EXPR_SUBSTRING:
t = gfc_specification_expr (e->ref->u.ss.start);
if (t == FAILURE)
break;
t = gfc_specification_expr (e->ref->u.ss.end);
if (t == SUCCESS)
t = gfc_simplify_expr (e, 0);
break;
case EXPR_STRUCTURE:
t = gfc_check_constructor (e, check_restricted);
break;
case EXPR_ARRAY:
t = gfc_check_constructor (e, check_restricted);
break;
default:
gfc_internal_error ("check_restricted(): Unknown expression type");
}
return t;
}
/* Check to see that an expression is a specification expression. If
we return FAILURE, an error has been generated. */
gfc_try
gfc_specification_expr (gfc_expr *e)
{
gfc_component *comp;
if (e == NULL)
return SUCCESS;
if (e->ts.type != BT_INTEGER)
{
gfc_error ("Expression at %L must be of INTEGER type, found %s",
&e->where, gfc_basic_typename (e->ts.type));
return FAILURE;
}
if (e->expr_type == EXPR_FUNCTION
&& !e->value.function.isym
&& !e->value.function.esym
&& !gfc_pure (e->symtree->n.sym)
&& (!gfc_is_proc_ptr_comp (e, &comp)
|| !comp->attr.pure))
{
gfc_error ("Function '%s' at %L must be PURE",
e->symtree->n.sym->name, &e->where);
/* Prevent repeat error messages. */
e->symtree->n.sym->attr.pure = 1;
return FAILURE;
}
if (e->rank != 0)
{
gfc_error ("Expression at %L must be scalar", &e->where);
return FAILURE;
}
if (gfc_simplify_expr (e, 0) == FAILURE)
return FAILURE;
return check_restricted (e);
}
/************** Expression conformance checks. *************/
/* Given two expressions, make sure that the arrays are conformable. */
gfc_try
gfc_check_conformance (gfc_expr *op1, gfc_expr *op2, const char *optype_msgid, ...)
{
int op1_flag, op2_flag, d;
mpz_t op1_size, op2_size;
gfc_try t;
va_list argp;
char buffer[240];
if (op1->rank == 0 || op2->rank == 0)
return SUCCESS;
va_start (argp, optype_msgid);
vsnprintf (buffer, 240, optype_msgid, argp);
va_end (argp);
if (op1->rank != op2->rank)
{
gfc_error ("Incompatible ranks in %s (%d and %d) at %L", _(buffer),
op1->rank, op2->rank, &op1->where);
return FAILURE;
}
t = SUCCESS;
for (d = 0; d < op1->rank; d++)
{
op1_flag = gfc_array_dimen_size (op1, d, &op1_size) == SUCCESS;
op2_flag = gfc_array_dimen_size (op2, d, &op2_size) == SUCCESS;
if (op1_flag && op2_flag && mpz_cmp (op1_size, op2_size) != 0)
{
gfc_error ("Different shape for %s at %L on dimension %d "
"(%d and %d)", _(buffer), &op1->where, d + 1,
(int) mpz_get_si (op1_size),
(int) mpz_get_si (op2_size));
t = FAILURE;
}
if (op1_flag)
mpz_clear (op1_size);
if (op2_flag)
mpz_clear (op2_size);
if (t == FAILURE)
return FAILURE;
}
return SUCCESS;
}
/* Given an assignable expression and an arbitrary expression, make
sure that the assignment can take place. */
gfc_try
gfc_check_assign (gfc_expr *lvalue, gfc_expr *rvalue, int conform)
{
gfc_symbol *sym;
gfc_ref *ref;
int has_pointer;
sym = lvalue->symtree->n.sym;
/* See if this is the component or subcomponent of a pointer. */
has_pointer = sym->attr.pointer;
for (ref = lvalue->ref; ref; ref = ref->next)
if (ref->type == REF_COMPONENT && ref->u.c.component->attr.pointer)
{
has_pointer = 1;
break;
}
/* 12.5.2.2, Note 12.26: The result variable is very similar to any other
variable local to a function subprogram. Its existence begins when
execution of the function is initiated and ends when execution of the
function is terminated...
Therefore, the left hand side is no longer a variable, when it is: */
if (sym->attr.flavor == FL_PROCEDURE && sym->attr.proc != PROC_ST_FUNCTION
&& !sym->attr.external)
{
bool bad_proc;
bad_proc = false;
/* (i) Use associated; */
if (sym->attr.use_assoc)
bad_proc = true;
/* (ii) The assignment is in the main program; or */
if (gfc_current_ns->proc_name->attr.is_main_program)
bad_proc = true;
/* (iii) A module or internal procedure... */
if ((gfc_current_ns->proc_name->attr.proc == PROC_INTERNAL
|| gfc_current_ns->proc_name->attr.proc == PROC_MODULE)
&& gfc_current_ns->parent
&& (!(gfc_current_ns->parent->proc_name->attr.function
|| gfc_current_ns->parent->proc_name->attr.subroutine)
|| gfc_current_ns->parent->proc_name->attr.is_main_program))
{
/* ... that is not a function... */
if (!gfc_current_ns->proc_name->attr.function)
bad_proc = true;
/* ... or is not an entry and has a different name. */
if (!sym->attr.entry && sym->name != gfc_current_ns->proc_name->name)
bad_proc = true;
}
/* (iv) Host associated and not the function symbol or the
parent result. This picks up sibling references, which
cannot be entries. */
if (!sym->attr.entry
&& sym->ns == gfc_current_ns->parent
&& sym != gfc_current_ns->proc_name
&& sym != gfc_current_ns->parent->proc_name->result)
bad_proc = true;
if (bad_proc)
{
gfc_error ("'%s' at %L is not a VALUE", sym->name, &lvalue->where);
return FAILURE;
}
}
if (rvalue->rank != 0 && lvalue->rank != rvalue->rank)
{
gfc_error ("Incompatible ranks %d and %d in assignment at %L",
lvalue->rank, rvalue->rank, &lvalue->where);
return FAILURE;
}
if (lvalue->ts.type == BT_UNKNOWN)
{
gfc_error ("Variable type is UNKNOWN in assignment at %L",
&lvalue->where);
return FAILURE;
}
if (rvalue->expr_type == EXPR_NULL)
{
if (has_pointer && (ref == NULL || ref->next == NULL)
&& lvalue->symtree->n.sym->attr.data)
return SUCCESS;
else
{
gfc_error ("NULL appears on right-hand side in assignment at %L",
&rvalue->where);
return FAILURE;
}
}
/* This is possibly a typo: x = f() instead of x => f(). */
if (gfc_option.warn_surprising
&& rvalue->expr_type == EXPR_FUNCTION
&& rvalue->symtree->n.sym->attr.pointer)
gfc_warning ("POINTER valued function appears on right-hand side of "
"assignment at %L", &rvalue->where);
/* Check size of array assignments. */
if (lvalue->rank != 0 && rvalue->rank != 0
&& gfc_check_conformance (lvalue, rvalue, "array assignment") != SUCCESS)
return FAILURE;
if (rvalue->is_boz && lvalue->ts.type != BT_INTEGER
&& lvalue->symtree->n.sym->attr.data
&& gfc_notify_std (GFC_STD_GNU, "Extension: BOZ literal at %L used to "
"initialize non-integer variable '%s'",
&rvalue->where, lvalue->symtree->n.sym->name)
== FAILURE)
return FAILURE;
else if (rvalue->is_boz && !lvalue->symtree->n.sym->attr.data
&& gfc_notify_std (GFC_STD_GNU, "Extension: BOZ literal at %L outside "
"a DATA statement and outside INT/REAL/DBLE/CMPLX",
&rvalue->where) == FAILURE)
return FAILURE;
/* Handle the case of a BOZ literal on the RHS. */
if (rvalue->is_boz && lvalue->ts.type != BT_INTEGER)
{
int rc;
if (gfc_option.warn_surprising)
gfc_warning ("BOZ literal at %L is bitwise transferred "
"non-integer symbol '%s'", &rvalue->where,
lvalue->symtree->n.sym->name);
if (!gfc_convert_boz (rvalue, &lvalue->ts))
return FAILURE;
if ((rc = gfc_range_check (rvalue)) != ARITH_OK)
{
if (rc == ARITH_UNDERFLOW)
gfc_error ("Arithmetic underflow of bit-wise transferred BOZ at %L"
". This check can be disabled with the option "
"-fno-range-check", &rvalue->where);
else if (rc == ARITH_OVERFLOW)
gfc_error ("Arithmetic overflow of bit-wise transferred BOZ at %L"
". This check can be disabled with the option "
"-fno-range-check", &rvalue->where);
else if (rc == ARITH_NAN)
gfc_error ("Arithmetic NaN of bit-wise transferred BOZ at %L"
". This check can be disabled with the option "
"-fno-range-check", &rvalue->where);
return FAILURE;
}
}
if (gfc_compare_types (&lvalue->ts, &rvalue->ts))
return SUCCESS;
/* Only DATA Statements come here. */
if (!conform)
{
/* Numeric can be converted to any other numeric. And Hollerith can be
converted to any other type. */
if ((gfc_numeric_ts (&lvalue->ts) && gfc_numeric_ts (&rvalue->ts))
|| rvalue->ts.type == BT_HOLLERITH)
return SUCCESS;
if (lvalue->ts.type == BT_LOGICAL && rvalue->ts.type == BT_LOGICAL)
return SUCCESS;
gfc_error ("Incompatible types in DATA statement at %L; attempted "
"conversion of %s to %s", &lvalue->where,
gfc_typename (&rvalue->ts), gfc_typename (&lvalue->ts));
return FAILURE;
}
/* Assignment is the only case where character variables of different
kind values can be converted into one another. */
if (lvalue->ts.type == BT_CHARACTER && rvalue->ts.type == BT_CHARACTER)
{
if (lvalue->ts.kind != rvalue->ts.kind)
gfc_convert_chartype (rvalue, &lvalue->ts);
return SUCCESS;
}
return gfc_convert_type (rvalue, &lvalue->ts, 1);
}
/* Check that a pointer assignment is OK. We first check lvalue, and
we only check rvalue if it's not an assignment to NULL() or a
NULLIFY statement. */
gfc_try
gfc_check_pointer_assign (gfc_expr *lvalue, gfc_expr *rvalue)
{
symbol_attribute attr;
gfc_ref *ref;
bool is_pure, is_implicit_pure, rank_remap;
int proc_pointer;
if (lvalue->symtree->n.sym->ts.type == BT_UNKNOWN
&& !lvalue->symtree->n.sym->attr.proc_pointer)
{
gfc_error ("Pointer assignment target is not a POINTER at %L",
&lvalue->where);
return FAILURE;
}
if (lvalue->symtree->n.sym->attr.flavor == FL_PROCEDURE
&& lvalue->symtree->n.sym->attr.use_assoc
&& !lvalue->symtree->n.sym->attr.proc_pointer)
{
gfc_error ("'%s' in the pointer assignment at %L cannot be an "
"l-value since it is a procedure",
lvalue->symtree->n.sym->name, &lvalue->where);
return FAILURE;
}
proc_pointer = lvalue->symtree->n.sym->attr.proc_pointer;
rank_remap = false;
for (ref = lvalue->ref; ref; ref = ref->next)
{
if (ref->type == REF_COMPONENT)
proc_pointer = ref->u.c.component->attr.proc_pointer;
if (ref->type == REF_ARRAY && ref->next == NULL)
{
int dim;
if (ref->u.ar.type == AR_FULL)
break;
if (ref->u.ar.type != AR_SECTION)
{
gfc_error ("Expected bounds specification for '%s' at %L",
lvalue->symtree->n.sym->name, &lvalue->where);
return FAILURE;
}
if (gfc_notify_std (GFC_STD_F2003,"Fortran 2003: Bounds "
"specification for '%s' in pointer assignment "
"at %L", lvalue->symtree->n.sym->name,
&lvalue->where) == FAILURE)
return FAILURE;
/* When bounds are given, all lbounds are necessary and either all
or none of the upper bounds; no strides are allowed. If the
upper bounds are present, we may do rank remapping. */
for (dim = 0; dim < ref->u.ar.dimen; ++dim)
{
if (!ref->u.ar.start[dim]
|| ref->u.ar.dimen_type[dim] != DIMEN_RANGE)
{
gfc_error ("Lower bound has to be present at %L",
&lvalue->where);
return FAILURE;
}
if (ref->u.ar.stride[dim])
{
gfc_error ("Stride must not be present at %L",
&lvalue->where);
return FAILURE;
}
if (dim == 0)
rank_remap = (ref->u.ar.end[dim] != NULL);
else
{
if ((rank_remap && !ref->u.ar.end[dim])
|| (!rank_remap && ref->u.ar.end[dim]))
{
gfc_error ("Either all or none of the upper bounds"
" must be specified at %L", &lvalue->where);
return FAILURE;
}
}
}
}
}
is_pure = gfc_pure (NULL);
is_implicit_pure = gfc_implicit_pure (NULL);
/* If rvalue is a NULL() or NULLIFY, we're done. Otherwise the type,
kind, etc for lvalue and rvalue must match, and rvalue must be a
pure variable if we're in a pure function. */
if (rvalue->expr_type == EXPR_NULL && rvalue->ts.type == BT_UNKNOWN)
return SUCCESS;
/* F2008, C723 (pointer) and C726 (proc-pointer); for PURE also C1283. */
if (lvalue->expr_type == EXPR_VARIABLE
&& gfc_is_coindexed (lvalue))
{
gfc_ref *ref;
for (ref = lvalue->ref; ref; ref = ref->next)
if (ref->type == REF_ARRAY && ref->u.ar.codimen)
{
gfc_error ("Pointer object at %L shall not have a coindex",
&lvalue->where);
return FAILURE;
}
}
/* Checks on rvalue for procedure pointer assignments. */
if (proc_pointer)
{
char err[200];
gfc_symbol *s1,*s2;
gfc_component *comp;
const char *name;
attr = gfc_expr_attr (rvalue);
if (!((rvalue->expr_type == EXPR_NULL)
|| (rvalue->expr_type == EXPR_FUNCTION && attr.proc_pointer)
|| (rvalue->expr_type == EXPR_VARIABLE && attr.proc_pointer)
|| (rvalue->expr_type == EXPR_VARIABLE
&& attr.flavor == FL_PROCEDURE)))
{
gfc_error ("Invalid procedure pointer assignment at %L",
&rvalue->where);
return FAILURE;
}
if (attr.abstract)
{
gfc_error ("Abstract interface '%s' is invalid "
"in procedure pointer assignment at %L",
rvalue->symtree->name, &rvalue->where);
return FAILURE;
}
/* Check for C727. */
if (attr.flavor == FL_PROCEDURE)
{
if (attr.proc == PROC_ST_FUNCTION)
{
gfc_error ("Statement function '%s' is invalid "
"in procedure pointer assignment at %L",
rvalue->symtree->name, &rvalue->where);
return FAILURE;
}
if (attr.proc == PROC_INTERNAL &&
gfc_notify_std (GFC_STD_F2008, "Internal procedure '%s' is "
"invalid in procedure pointer assignment at %L",
rvalue->symtree->name, &rvalue->where) == FAILURE)
return FAILURE;
}
/* Ensure that the calling convention is the same. As other attributes
such as DLLEXPORT may differ, one explicitly only tests for the
calling conventions. */
if (rvalue->expr_type == EXPR_VARIABLE
&& lvalue->symtree->n.sym->attr.ext_attr
!= rvalue->symtree->n.sym->attr.ext_attr)
{
symbol_attribute calls;
calls.ext_attr = 0;
gfc_add_ext_attribute (&calls, EXT_ATTR_CDECL, NULL);
gfc_add_ext_attribute (&calls, EXT_ATTR_STDCALL, NULL);
gfc_add_ext_attribute (&calls, EXT_ATTR_FASTCALL, NULL);
if ((calls.ext_attr & lvalue->symtree->n.sym->attr.ext_attr)
!= (calls.ext_attr & rvalue->symtree->n.sym->attr.ext_attr))
{
gfc_error ("Mismatch in the procedure pointer assignment "
"at %L: mismatch in the calling convention",
&rvalue->where);
return FAILURE;
}
}
if (gfc_is_proc_ptr_comp (lvalue, &comp))
s1 = comp->ts.interface;
else
s1 = lvalue->symtree->n.sym;
if (gfc_is_proc_ptr_comp (rvalue, &comp))
{
s2 = comp->ts.interface;
name = comp->name;
}
else if (rvalue->expr_type == EXPR_FUNCTION)
{
s2 = rvalue->symtree->n.sym->result;
name = rvalue->symtree->n.sym->result->name;
}
else
{
s2 = rvalue->symtree->n.sym;
name = rvalue->symtree->n.sym->name;
}
if (s1 && s2 && !gfc_compare_interfaces (s1, s2, name, 0, 1,
err, sizeof(err)))
{
gfc_error ("Interface mismatch in procedure pointer assignment "
"at %L: %s", &rvalue->where, err);
return FAILURE;
}
return SUCCESS;
}
if (!gfc_compare_types (&lvalue->ts, &rvalue->ts))
{
gfc_error ("Different types in pointer assignment at %L; attempted "
"assignment of %s to %s", &lvalue->where,
gfc_typename (&rvalue->ts), gfc_typename (&lvalue->ts));
return FAILURE;
}
if (lvalue->ts.type != BT_CLASS && lvalue->ts.kind != rvalue->ts.kind)
{
gfc_error ("Different kind type parameters in pointer "
"assignment at %L", &lvalue->where);
return FAILURE;
}
if (lvalue->rank != rvalue->rank && !rank_remap)
{
gfc_error ("Different ranks in pointer assignment at %L", &lvalue->where);
return FAILURE;
}
if (lvalue->ts.type == BT_CLASS && rvalue->ts.type == BT_DERIVED)
/* Make sure the vtab is present. */
gfc_find_derived_vtab (rvalue->ts.u.derived);
/* Check rank remapping. */
if (rank_remap)
{
mpz_t lsize, rsize;
/* If this can be determined, check that the target must be at least as
large as the pointer assigned to it is. */
if (gfc_array_size (lvalue, &lsize) == SUCCESS
&& gfc_array_size (rvalue, &rsize) == SUCCESS
&& mpz_cmp (rsize, lsize) < 0)
{
gfc_error ("Rank remapping target is smaller than size of the"
" pointer (%ld < %ld) at %L",
mpz_get_si (rsize), mpz_get_si (lsize),
&lvalue->where);
return FAILURE;
}
/* The target must be either rank one or it must be simply contiguous
and F2008 must be allowed. */
if (rvalue->rank != 1)
{
if (!gfc_is_simply_contiguous (rvalue, true))
{
gfc_error ("Rank remapping target must be rank 1 or"
" simply contiguous at %L", &rvalue->where);
return FAILURE;
}
if (gfc_notify_std (GFC_STD_F2008, "Fortran 2008: Rank remapping"
" target is not rank 1 at %L", &rvalue->where)
== FAILURE)
return FAILURE;
}
}
/* Now punt if we are dealing with a NULLIFY(X) or X = NULL(X). */
if (rvalue->expr_type == EXPR_NULL)
return SUCCESS;
if (lvalue->ts.type == BT_CHARACTER)
{
gfc_try t = gfc_check_same_strlen (lvalue, rvalue, "pointer assignment");
if (t == FAILURE)
return FAILURE;
}
if (rvalue->expr_type == EXPR_VARIABLE && is_subref_array (rvalue))
lvalue->symtree->n.sym->attr.subref_array_pointer = 1;
attr = gfc_expr_attr (rvalue);
if (rvalue->expr_type == EXPR_FUNCTION && !attr.pointer)
{
gfc_error ("Target expression in pointer assignment "
"at %L must deliver a pointer result",
&rvalue->where);
return FAILURE;
}
if (!attr.target && !attr.pointer)
{
gfc_error ("Pointer assignment target is neither TARGET "
"nor POINTER at %L", &rvalue->where);
return FAILURE;
}
if (is_pure && gfc_impure_variable (rvalue->symtree->n.sym))
{
gfc_error ("Bad target in pointer assignment in PURE "
"procedure at %L", &rvalue->where);
}
if (is_implicit_pure && gfc_impure_variable (rvalue->symtree->n.sym))
gfc_current_ns->proc_name->attr.implicit_pure = 0;
if (gfc_has_vector_index (rvalue))
{
gfc_error ("Pointer assignment with vector subscript "
"on rhs at %L", &rvalue->where);
return FAILURE;
}
if (attr.is_protected && attr.use_assoc
&& !(attr.pointer || attr.proc_pointer))
{
gfc_error ("Pointer assignment target has PROTECTED "
"attribute at %L", &rvalue->where);
return FAILURE;
}
/* F2008, C725. For PURE also C1283. */
if (rvalue->expr_type == EXPR_VARIABLE
&& gfc_is_coindexed (rvalue))
{
gfc_ref *ref;
for (ref = rvalue->ref; ref; ref = ref->next)
if (ref->type == REF_ARRAY && ref->u.ar.codimen)
{
gfc_error ("Data target at %L shall not have a coindex",
&rvalue->where);
return FAILURE;
}
}
return SUCCESS;
}
/* Relative of gfc_check_assign() except that the lvalue is a single
symbol. Used for initialization assignments. */
gfc_try
gfc_check_assign_symbol (gfc_symbol *sym, gfc_expr *rvalue)
{
gfc_expr lvalue;
gfc_try r;
memset (&lvalue, '\0', sizeof (gfc_expr));
lvalue.expr_type = EXPR_VARIABLE;
lvalue.ts = sym->ts;
if (sym->as)
lvalue.rank = sym->as->rank;
lvalue.symtree = XCNEW (gfc_symtree);
lvalue.symtree->n.sym = sym;
lvalue.where = sym->declared_at;
if (sym->attr.pointer || sym->attr.proc_pointer
|| (sym->ts.type == BT_CLASS && CLASS_DATA (sym)->attr.class_pointer
&& rvalue->expr_type == EXPR_NULL))
r = gfc_check_pointer_assign (&lvalue, rvalue);
else
r = gfc_check_assign (&lvalue, rvalue, 1);
free (lvalue.symtree);
if (r == FAILURE)
return r;
if (sym->attr.pointer && rvalue->expr_type != EXPR_NULL)
{
/* F08:C461. Additional checks for pointer initialization. */
symbol_attribute attr;
attr = gfc_expr_attr (rvalue);
if (attr.allocatable)
{
gfc_error ("Pointer initialization target at %C "
"must not be ALLOCATABLE ");
return FAILURE;
}
if (!attr.target || attr.pointer)
{
gfc_error ("Pointer initialization target at %C "
"must have the TARGET attribute");
return FAILURE;
}
if (!attr.save)
{
gfc_error ("Pointer initialization target at %C "
"must have the SAVE attribute");
return FAILURE;
}
}
if (sym->attr.proc_pointer && rvalue->expr_type != EXPR_NULL)
{
/* F08:C1220. Additional checks for procedure pointer initialization. */
symbol_attribute attr = gfc_expr_attr (rvalue);
if (attr.proc_pointer)
{
gfc_error ("Procedure pointer initialization target at %L "
"may not be a procedure pointer", &rvalue->where);
return FAILURE;
}
}
return SUCCESS;
}
/* Check for default initializer; sym->value is not enough
as it is also set for EXPR_NULL of allocatables. */
bool
gfc_has_default_initializer (gfc_symbol *der)
{
gfc_component *c;
gcc_assert (der->attr.flavor == FL_DERIVED);
for (c = der->components; c; c = c->next)
if (c->ts.type == BT_DERIVED)
{
if (!c->attr.pointer
&& gfc_has_default_initializer (c->ts.u.derived))
return true;
}
else
{
if (c->initializer)
return true;
}
return false;
}
/* Get an expression for a default initializer. */
gfc_expr *
gfc_default_initializer (gfc_typespec *ts)
{
gfc_expr *init;
gfc_component *comp;
/* See if we have a default initializer in this, but not in nested
types (otherwise we could use gfc_has_default_initializer()). */
for (comp = ts->u.derived->components; comp; comp = comp->next)
if (comp->initializer || comp->attr.allocatable
|| (comp->ts.type == BT_CLASS && CLASS_DATA (comp)->attr.allocatable))
break;
if (!comp)
return NULL;
init = gfc_get_structure_constructor_expr (ts->type, ts->kind,
&ts->u.derived->declared_at);
init->ts = *ts;
for (comp = ts->u.derived->components; comp; comp = comp->next)
{
gfc_constructor *ctor = gfc_constructor_get();
if (comp->initializer)
ctor->expr = gfc_copy_expr (comp->initializer);
if (comp->attr.allocatable
|| (comp->ts.type == BT_CLASS && CLASS_DATA (comp)->attr.allocatable))
{
ctor->expr = gfc_get_expr ();
ctor->expr->expr_type = EXPR_NULL;
ctor->expr->ts = comp->ts;
}
gfc_constructor_append (&init->value.constructor, ctor);
}
return init;
}
/* Given a symbol, create an expression node with that symbol as a
variable. If the symbol is array valued, setup a reference of the
whole array. */
gfc_expr *
gfc_get_variable_expr (gfc_symtree *var)
{
gfc_expr *e;
e = gfc_get_expr ();
e->expr_type = EXPR_VARIABLE;
e->symtree = var;
e->ts = var->n.sym->ts;
if (var->n.sym->as != NULL)
{
e->rank = var->n.sym->as->rank;
e->ref = gfc_get_ref ();
e->ref->type = REF_ARRAY;
e->ref->u.ar.type = AR_FULL;
}
return e;
}
gfc_expr *
gfc_lval_expr_from_sym (gfc_symbol *sym)
{
gfc_expr *lval;
lval = gfc_get_expr ();
lval->expr_type = EXPR_VARIABLE;
lval->where = sym->declared_at;
lval->ts = sym->ts;
lval->symtree = gfc_find_symtree (sym->ns->sym_root, sym->name);
/* It will always be a full array. */
lval->rank = sym->as ? sym->as->rank : 0;
if (lval->rank)
{
lval->ref = gfc_get_ref ();
lval->ref->type = REF_ARRAY;
lval->ref->u.ar.type = AR_FULL;
lval->ref->u.ar.dimen = lval->rank;
lval->ref->u.ar.where = sym->declared_at;
lval->ref->u.ar.as = sym->as;
}
return lval;
}
/* Returns the array_spec of a full array expression. A NULL is
returned otherwise. */
gfc_array_spec *
gfc_get_full_arrayspec_from_expr (gfc_expr *expr)
{
gfc_array_spec *as;
gfc_ref *ref;
if (expr->rank == 0)
return NULL;
/* Follow any component references. */
if (expr->expr_type == EXPR_VARIABLE
|| expr->expr_type == EXPR_CONSTANT)
{
as = expr->symtree->n.sym->as;
for (ref = expr->ref; ref; ref = ref->next)
{
switch (ref->type)
{
case REF_COMPONENT:
as = ref->u.c.component->as;
continue;
case REF_SUBSTRING:
continue;
case REF_ARRAY:
{
switch (ref->u.ar.type)
{
case AR_ELEMENT:
case AR_SECTION:
case AR_UNKNOWN:
as = NULL;
continue;
case AR_FULL:
break;
}
break;
}
}
}
}
else
as = NULL;
return as;
}
/* General expression traversal function. */
bool
gfc_traverse_expr (gfc_expr *expr, gfc_symbol *sym,
bool (*func)(gfc_expr *, gfc_symbol *, int*),
int f)
{
gfc_array_ref ar;
gfc_ref *ref;
gfc_actual_arglist *args;
gfc_constructor *c;
int i;
if (!expr)
return false;
if ((*func) (expr, sym, &f))
return true;
if (expr->ts.type == BT_CHARACTER
&& expr->ts.u.cl
&& expr->ts.u.cl->length
&& expr->ts.u.cl->length->expr_type != EXPR_CONSTANT
&& gfc_traverse_expr (expr->ts.u.cl->length, sym, func, f))
return true;
switch (expr->expr_type)
{
case EXPR_PPC:
case EXPR_COMPCALL:
case EXPR_FUNCTION:
for (args = expr->value.function.actual; args; args = args->next)
{
if (gfc_traverse_expr (args->expr, sym, func, f))
return true;
}
break;
case EXPR_VARIABLE:
case EXPR_CONSTANT:
case EXPR_NULL:
case EXPR_SUBSTRING:
break;
case EXPR_STRUCTURE:
case EXPR_ARRAY:
for (c = gfc_constructor_first (expr->value.constructor);
c; c = gfc_constructor_next (c))
{
if (gfc_traverse_expr (c->expr, sym, func, f))
return true;
if (c->iterator)
{
if (gfc_traverse_expr (c->iterator->var, sym, func, f))
return true;
if (gfc_traverse_expr (c->iterator->start, sym, func, f))
return true;
if (gfc_traverse_expr (c->iterator->end, sym, func, f))
return true;
if (gfc_traverse_expr (c->iterator->step, sym, func, f))
return true;
}
}
break;
case EXPR_OP:
if (gfc_traverse_expr (expr->value.op.op1, sym, func, f))
return true;
if (gfc_traverse_expr (expr->value.op.op2, sym, func, f))
return true;
break;
default:
gcc_unreachable ();
break;
}
ref = expr->ref;
while (ref != NULL)
{
switch (ref->type)
{
case REF_ARRAY:
ar = ref->u.ar;
for (i = 0; i < GFC_MAX_DIMENSIONS; i++)
{
if (gfc_traverse_expr (ar.start[i], sym, func, f))
return true;
if (gfc_traverse_expr (ar.end[i], sym, func, f))
return true;
if (gfc_traverse_expr (ar.stride[i], sym, func, f))
return true;
}
break;
case REF_SUBSTRING:
if (gfc_traverse_expr (ref->u.ss.start, sym, func, f))
return true;
if (gfc_traverse_expr (ref->u.ss.end, sym, func, f))
return true;
break;
case REF_COMPONENT:
if (ref->u.c.component->ts.type == BT_CHARACTER
&& ref->u.c.component->ts.u.cl
&& ref->u.c.component->ts.u.cl->length
&& ref->u.c.component->ts.u.cl->length->expr_type
!= EXPR_CONSTANT
&& gfc_traverse_expr (ref->u.c.component->ts.u.cl->length,
sym, func, f))
return true;
if (ref->u.c.component->as)
for (i = 0; i < ref->u.c.component->as->rank
+ ref->u.c.component->as->corank; i++)
{
if (gfc_traverse_expr (ref->u.c.component->as->lower[i],
sym, func, f))
return true;
if (gfc_traverse_expr (ref->u.c.component->as->upper[i],
sym, func, f))
return true;
}
break;
default:
gcc_unreachable ();
}
ref = ref->next;
}
return false;
}
/* Traverse expr, marking all EXPR_VARIABLE symbols referenced. */
static bool
expr_set_symbols_referenced (gfc_expr *expr,
gfc_symbol *sym ATTRIBUTE_UNUSED,
int *f ATTRIBUTE_UNUSED)
{
if (expr->expr_type != EXPR_VARIABLE)
return false;
gfc_set_sym_referenced (expr->symtree->n.sym);
return false;
}
void
gfc_expr_set_symbols_referenced (gfc_expr *expr)
{
gfc_traverse_expr (expr, NULL, expr_set_symbols_referenced, 0);
}
/* Determine if an expression is a procedure pointer component. If yes, the
argument 'comp' will point to the component (provided that 'comp' was
provided). */
bool
gfc_is_proc_ptr_comp (gfc_expr *expr, gfc_component **comp)
{
gfc_ref *ref;
bool ppc = false;
if (!expr || !expr->ref)
return false;
ref = expr->ref;
while (ref->next)
ref = ref->next;
if (ref->type == REF_COMPONENT)
{
ppc = ref->u.c.component->attr.proc_pointer;
if (ppc && comp)
*comp = ref->u.c.component;
}
return ppc;
}
/* Walk an expression tree and check each variable encountered for being typed.
If strict is not set, a top-level variable is tolerated untyped in -std=gnu
mode as is a basic arithmetic expression using those; this is for things in
legacy-code like:
INTEGER :: arr(n), n
INTEGER :: arr(n + 1), n
The namespace is needed for IMPLICIT typing. */
static gfc_namespace* check_typed_ns;
static bool
expr_check_typed_help (gfc_expr* e, gfc_symbol* sym ATTRIBUTE_UNUSED,
int* f ATTRIBUTE_UNUSED)
{
gfc_try t;
if (e->expr_type != EXPR_VARIABLE)
return false;
gcc_assert (e->symtree);
t = gfc_check_symbol_typed (e->symtree->n.sym, check_typed_ns,
true, e->where);
return (t == FAILURE);
}
gfc_try
gfc_expr_check_typed (gfc_expr* e, gfc_namespace* ns, bool strict)
{
bool error_found;
/* If this is a top-level variable or EXPR_OP, do the check with strict given
to us. */
if (!strict)
{
if (e->expr_type == EXPR_VARIABLE && !e->ref)
return gfc_check_symbol_typed (e->symtree->n.sym, ns, strict, e->where);
if (e->expr_type == EXPR_OP)
{
gfc_try t = SUCCESS;
gcc_assert (e->value.op.op1);
t = gfc_expr_check_typed (e->value.op.op1, ns, strict);
if (t == SUCCESS && e->value.op.op2)
t = gfc_expr_check_typed (e->value.op.op2, ns, strict);
return t;
}
}
/* Otherwise, walk the expression and do it strictly. */
check_typed_ns = ns;
error_found = gfc_traverse_expr (e, NULL, &expr_check_typed_help, 0);
return error_found ? FAILURE : SUCCESS;
}
/* Walk an expression tree and replace all symbols with a corresponding symbol
in the formal_ns of "sym". Needed for copying interfaces in PROCEDURE
statements. The boolean return value is required by gfc_traverse_expr. */
static bool
replace_symbol (gfc_expr *expr, gfc_symbol *sym, int *i ATTRIBUTE_UNUSED)
{
if ((expr->expr_type == EXPR_VARIABLE
|| (expr->expr_type == EXPR_FUNCTION
&& !gfc_is_intrinsic (expr->symtree->n.sym, 0, expr->where)))
&& expr->symtree->n.sym->ns == sym->ts.interface->formal_ns)
{
gfc_symtree *stree;
gfc_namespace *ns = sym->formal_ns;
/* Don't use gfc_get_symtree as we prefer to fail badly if we don't find
the symtree rather than create a new one (and probably fail later). */
stree = gfc_find_symtree (ns ? ns->sym_root : gfc_current_ns->sym_root,
expr->symtree->n.sym->name);
gcc_assert (stree);
stree->n.sym->attr = expr->symtree->n.sym->attr;
expr->symtree = stree;
}
return false;
}
void
gfc_expr_replace_symbols (gfc_expr *expr, gfc_symbol *dest)
{
gfc_traverse_expr (expr, dest, &replace_symbol, 0);
}
/* The following is analogous to 'replace_symbol', and needed for copying
interfaces for procedure pointer components. The argument 'sym' must formally
be a gfc_symbol, so that the function can be passed to gfc_traverse_expr.
However, it gets actually passed a gfc_component (i.e. the procedure pointer
component in whose formal_ns the arguments have to be). */
static bool
replace_comp (gfc_expr *expr, gfc_symbol *sym, int *i ATTRIBUTE_UNUSED)
{
gfc_component *comp;
comp = (gfc_component *)sym;
if ((expr->expr_type == EXPR_VARIABLE
|| (expr->expr_type == EXPR_FUNCTION
&& !gfc_is_intrinsic (expr->symtree->n.sym, 0, expr->where)))
&& expr->symtree->n.sym->ns == comp->ts.interface->formal_ns)
{
gfc_symtree *stree;
gfc_namespace *ns = comp->formal_ns;
/* Don't use gfc_get_symtree as we prefer to fail badly if we don't find
the symtree rather than create a new one (and probably fail later). */
stree = gfc_find_symtree (ns ? ns->sym_root : gfc_current_ns->sym_root,
expr->symtree->n.sym->name);
gcc_assert (stree);
stree->n.sym->attr = expr->symtree->n.sym->attr;
expr->symtree = stree;
}
return false;
}
void
gfc_expr_replace_comp (gfc_expr *expr, gfc_component *dest)
{
gfc_traverse_expr (expr, (gfc_symbol *)dest, &replace_comp, 0);
}
bool
gfc_ref_this_image (gfc_ref *ref)
{
int n;
gcc_assert (ref->type == REF_ARRAY && ref->u.ar.codimen > 0);
for (n = ref->u.ar.dimen; n < ref->u.ar.dimen + ref->u.ar.codimen; n++)
if (ref->u.ar.dimen_type[n] != DIMEN_THIS_IMAGE)
return false;
return true;
}
bool
gfc_is_coindexed (gfc_expr *e)
{
gfc_ref *ref;
for (ref = e->ref; ref; ref = ref->next)
if (ref->type == REF_ARRAY && ref->u.ar.codimen > 0)
return !gfc_ref_this_image (ref);
return false;
}
/* Coarrays are variables with a corank but not being coindexed. However, also
the following is a coarray: A subobject of a coarray is a coarray if it does
not have any cosubscripts, vector subscripts, allocatable component
selection, or pointer component selection. (F2008, 2.4.7) */
bool
gfc_is_coarray (gfc_expr *e)
{
gfc_ref *ref;
gfc_symbol *sym;
gfc_component *comp;
bool coindexed;
bool coarray;
int i;
if (e->expr_type != EXPR_VARIABLE)
return false;
coindexed = false;
sym = e->symtree->n.sym;
if (sym->ts.type == BT_CLASS && sym->attr.class_ok)
coarray = CLASS_DATA (sym)->attr.codimension;
else
coarray = sym->attr.codimension;
for (ref = e->ref; ref; ref = ref->next)
switch (ref->type)
{
case REF_COMPONENT:
comp = ref->u.c.component;
if (comp->attr.pointer || comp->attr.allocatable)
{
coindexed = false;
if (comp->ts.type == BT_CLASS && comp->attr.class_ok)
coarray = CLASS_DATA (comp)->attr.codimension;
else
coarray = comp->attr.codimension;
}
break;
case REF_ARRAY:
if (!coarray)
break;
if (ref->u.ar.codimen > 0 && !gfc_ref_this_image (ref))
{
coindexed = true;
break;
}
for (i = 0; i < ref->u.ar.dimen; i++)
if (ref->u.ar.dimen_type[i] == DIMEN_VECTOR)
{
coarray = false;
break;
}
break;
case REF_SUBSTRING:
break;
}
return coarray && !coindexed;
}
int
gfc_get_corank (gfc_expr *e)
{
int corank;
gfc_ref *ref;
corank = e->symtree->n.sym->as ? e->symtree->n.sym->as->corank : 0;
for (ref = e->ref; ref; ref = ref->next)
{
if (ref->type == REF_ARRAY)
corank = ref->u.ar.as->corank;
gcc_assert (ref->type != REF_SUBSTRING);
}
return corank;
}
/* Check whether the expression has an ultimate allocatable component.
Being itself allocatable does not count. */
bool
gfc_has_ultimate_allocatable (gfc_expr *e)
{
gfc_ref *ref, *last = NULL;
if (e->expr_type != EXPR_VARIABLE)
return false;
for (ref = e->ref; ref; ref = ref->next)
if (ref->type == REF_COMPONENT)
last = ref;
if (last && last->u.c.component->ts.type == BT_CLASS)
return CLASS_DATA (last->u.c.component)->attr.alloc_comp;
else if (last && last->u.c.component->ts.type == BT_DERIVED)
return last->u.c.component->ts.u.derived->attr.alloc_comp;
else if (last)
return false;
if (e->ts.type == BT_CLASS)
return CLASS_DATA (e)->attr.alloc_comp;
else if (e->ts.type == BT_DERIVED)
return e->ts.u.derived->attr.alloc_comp;
else
return false;
}
/* Check whether the expression has an pointer component.
Being itself a pointer does not count. */
bool
gfc_has_ultimate_pointer (gfc_expr *e)
{
gfc_ref *ref, *last = NULL;
if (e->expr_type != EXPR_VARIABLE)
return false;
for (ref = e->ref; ref; ref = ref->next)
if (ref->type == REF_COMPONENT)
last = ref;
if (last && last->u.c.component->ts.type == BT_CLASS)
return CLASS_DATA (last->u.c.component)->attr.pointer_comp;
else if (last && last->u.c.component->ts.type == BT_DERIVED)
return last->u.c.component->ts.u.derived->attr.pointer_comp;
else if (last)
return false;
if (e->ts.type == BT_CLASS)
return CLASS_DATA (e)->attr.pointer_comp;
else if (e->ts.type == BT_DERIVED)
return e->ts.u.derived->attr.pointer_comp;
else
return false;
}
/* Check whether an expression is "simply contiguous", cf. F2008, 6.5.4.
Note: A scalar is not regarded as "simply contiguous" by the standard.
if bool is not strict, some futher checks are done - for instance,
a "(::1)" is accepted. */
bool
gfc_is_simply_contiguous (gfc_expr *expr, bool strict)
{
bool colon;
int i;
gfc_array_ref *ar = NULL;
gfc_ref *ref, *part_ref = NULL;
if (expr->expr_type == EXPR_FUNCTION)
return expr->value.function.esym
? expr->value.function.esym->result->attr.contiguous : false;
else if (expr->expr_type != EXPR_VARIABLE)
return false;
if (expr->rank == 0)
return false;
for (ref = expr->ref; ref; ref = ref->next)
{
if (ar)
return false; /* Array shall be last part-ref. */
if (ref->type == REF_COMPONENT)
part_ref = ref;
else if (ref->type == REF_SUBSTRING)
return false;
else if (ref->u.ar.type != AR_ELEMENT)
ar = &ref->u.ar;
}
if ((part_ref && !part_ref->u.c.component->attr.contiguous
&& part_ref->u.c.component->attr.pointer)
|| (!part_ref && !expr->symtree->n.sym->attr.contiguous
&& (expr->symtree->n.sym->attr.pointer
|| expr->symtree->n.sym->as->type == AS_ASSUMED_SHAPE)))
return false;
if (!ar || ar->type == AR_FULL)
return true;
gcc_assert (ar->type == AR_SECTION);
/* Check for simply contiguous array */
colon = true;
for (i = 0; i < ar->dimen; i++)
{
if (ar->dimen_type[i] == DIMEN_VECTOR)
return false;
if (ar->dimen_type[i] == DIMEN_ELEMENT)
{
colon = false;
continue;
}
gcc_assert (ar->dimen_type[i] == DIMEN_RANGE);
/* If the previous section was not contiguous, that's an error,
unless we have effective only one element and checking is not
strict. */
if (!colon && (strict || !ar->start[i] || !ar->end[i]
|| ar->start[i]->expr_type != EXPR_CONSTANT
|| ar->end[i]->expr_type != EXPR_CONSTANT
|| mpz_cmp (ar->start[i]->value.integer,
ar->end[i]->value.integer) != 0))
return false;
/* Following the standard, "(::1)" or - if known at compile time -
"(lbound:ubound)" are not simply contigous; if strict
is false, they are regarded as simply contiguous. */
if (ar->stride[i] && (strict || ar->stride[i]->expr_type != EXPR_CONSTANT
|| ar->stride[i]->ts.type != BT_INTEGER
|| mpz_cmp_si (ar->stride[i]->value.integer, 1) != 0))
return false;
if (ar->start[i]
&& (strict || ar->start[i]->expr_type != EXPR_CONSTANT
|| !ar->as->lower[i]
|| ar->as->lower[i]->expr_type != EXPR_CONSTANT
|| mpz_cmp (ar->start[i]->value.integer,
ar->as->lower[i]->value.integer) != 0))
colon = false;
if (ar->end[i]
&& (strict || ar->end[i]->expr_type != EXPR_CONSTANT
|| !ar->as->upper[i]
|| ar->as->upper[i]->expr_type != EXPR_CONSTANT
|| mpz_cmp (ar->end[i]->value.integer,
ar->as->upper[i]->value.integer) != 0))
colon = false;
}
return true;
}
/* Build call to an intrinsic procedure. The number of arguments has to be
passed (rather than ending the list with a NULL value) because we may
want to add arguments but with a NULL-expression. */
gfc_expr*
gfc_build_intrinsic_call (const char* name, locus where, unsigned numarg, ...)
{
gfc_expr* result;
gfc_actual_arglist* atail;
gfc_intrinsic_sym* isym;
va_list ap;
unsigned i;
isym = gfc_find_function (name);
gcc_assert (isym);
result = gfc_get_expr ();
result->expr_type = EXPR_FUNCTION;
result->ts = isym->ts;
result->where = where;
result->value.function.name = name;
result->value.function.isym = isym;
va_start (ap, numarg);
atail = NULL;
for (i = 0; i < numarg; ++i)
{
if (atail)
{
atail->next = gfc_get_actual_arglist ();
atail = atail->next;
}
else
atail = result->value.function.actual = gfc_get_actual_arglist ();
atail->expr = va_arg (ap, gfc_expr*);
}
va_end (ap);
return result;
}
/* Check if an expression may appear in a variable definition context
(F2008, 16.6.7) or pointer association context (F2008, 16.6.8).
This is called from the various places when resolving
the pieces that make up such a context.
Optionally, a possible error message can be suppressed if context is NULL
and just the return status (SUCCESS / FAILURE) be requested. */
gfc_try
gfc_check_vardef_context (gfc_expr* e, bool pointer, bool alloc_obj,
const char* context)
{
gfc_symbol* sym = NULL;
bool is_pointer;
bool check_intentin;
bool ptr_component;
symbol_attribute attr;
gfc_ref* ref;
if (e->expr_type == EXPR_VARIABLE)
{
gcc_assert (e->symtree);
sym = e->symtree->n.sym;
}
else if (e->expr_type == EXPR_FUNCTION)
{
gcc_assert (e->symtree);
sym = e->value.function.esym ? e->value.function.esym : e->symtree->n.sym;
}
attr = gfc_expr_attr (e);
if (!pointer && e->expr_type == EXPR_FUNCTION && attr.pointer)
{
if (!(gfc_option.allow_std & GFC_STD_F2008))
{
if (context)
gfc_error ("Fortran 2008: Pointer functions in variable definition"
" context (%s) at %L", context, &e->where);
return FAILURE;
}
}
else if (e->expr_type != EXPR_VARIABLE)
{
if (context)
gfc_error ("Non-variable expression in variable definition context (%s)"
" at %L", context, &e->where);
return FAILURE;
}
if (!pointer && sym->attr.flavor == FL_PARAMETER)
{
if (context)
gfc_error ("Named constant '%s' in variable definition context (%s)"
" at %L", sym->name, context, &e->where);
return FAILURE;
}
if (!pointer && sym->attr.flavor != FL_VARIABLE
&& !(sym->attr.flavor == FL_PROCEDURE && sym == sym->result)
&& !(sym->attr.flavor == FL_PROCEDURE && sym->attr.proc_pointer))
{
if (context)
gfc_error ("'%s' in variable definition context (%s) at %L is not"
" a variable", sym->name, context, &e->where);
return FAILURE;
}
/* Find out whether the expr is a pointer; this also means following
component references to the last one. */
is_pointer = (attr.pointer || attr.proc_pointer);
if (pointer && !is_pointer)
{
if (context)
gfc_error ("Non-POINTER in pointer association context (%s)"
" at %L", context, &e->where);
return FAILURE;
}
/* F2008, C1303. */
if (!alloc_obj
&& (attr.lock_comp
|| (e->ts.type == BT_DERIVED
&& e->ts.u.derived->from_intmod == INTMOD_ISO_FORTRAN_ENV
&& e->ts.u.derived->intmod_sym_id == ISOFORTRAN_LOCK_TYPE)))
{
if (context)
gfc_error ("LOCK_TYPE in variable definition context (%s) at %L",
context, &e->where);
return FAILURE;
}
/* INTENT(IN) dummy argument. Check this, unless the object itself is
the component of sub-component of a pointer. Obviously,
procedure pointers are of no interest here. */
check_intentin = true;
ptr_component = sym->attr.pointer;
for (ref = e->ref; ref && check_intentin; ref = ref->next)
{
if (ptr_component && ref->type == REF_COMPONENT)
check_intentin = false;
if (ref->type == REF_COMPONENT && ref->u.c.component->attr.pointer)
ptr_component = true;
}
if (check_intentin && sym->attr.intent == INTENT_IN)
{
if (pointer && is_pointer)
{
if (context)
gfc_error ("Dummy argument '%s' with INTENT(IN) in pointer"
" association context (%s) at %L",
sym->name, context, &e->where);
return FAILURE;
}
if (!pointer && !is_pointer)
{
if (context)
gfc_error ("Dummy argument '%s' with INTENT(IN) in variable"
" definition context (%s) at %L",
sym->name, context, &e->where);
return FAILURE;
}
}
/* PROTECTED and use-associated. */
if (sym->attr.is_protected && sym->attr.use_assoc && check_intentin)
{
if (pointer && is_pointer)
{
if (context)
gfc_error ("Variable '%s' is PROTECTED and can not appear in a"
" pointer association context (%s) at %L",
sym->name, context, &e->where);
return FAILURE;
}
if (!pointer && !is_pointer)
{
if (context)
gfc_error ("Variable '%s' is PROTECTED and can not appear in a"
" variable definition context (%s) at %L",
sym->name, context, &e->where);
return FAILURE;
}
}
/* Variable not assignable from a PURE procedure but appears in
variable definition context. */
if (!pointer && gfc_pure (NULL) && gfc_impure_variable (sym))
{
if (context)
gfc_error ("Variable '%s' can not appear in a variable definition"
" context (%s) at %L in PURE procedure",
sym->name, context, &e->where);
return FAILURE;
}
if (!pointer && gfc_implicit_pure (NULL) && gfc_impure_variable (sym))
gfc_current_ns->proc_name->attr.implicit_pure = 0;
/* Check variable definition context for associate-names. */
if (!pointer && sym->assoc)
{
const char* name;
gfc_association_list* assoc;
gcc_assert (sym->assoc->target);
/* If this is a SELECT TYPE temporary (the association is used internally
for SELECT TYPE), silently go over to the target. */
if (sym->attr.select_type_temporary)
{
gfc_expr* t = sym->assoc->target;
gcc_assert (t->expr_type == EXPR_VARIABLE);
name = t->symtree->name;
if (t->symtree->n.sym->assoc)
assoc = t->symtree->n.sym->assoc;
else
assoc = sym->assoc;
}
else
{
name = sym->name;
assoc = sym->assoc;
}
gcc_assert (name && assoc);
/* Is association to a valid variable? */
if (!assoc->variable)
{
if (context)
{
if (assoc->target->expr_type == EXPR_VARIABLE)
gfc_error ("'%s' at %L associated to vector-indexed target can"
" not be used in a variable definition context (%s)",
name, &e->where, context);
else
gfc_error ("'%s' at %L associated to expression can"
" not be used in a variable definition context (%s)",
name, &e->where, context);
}
return FAILURE;
}
/* Target must be allowed to appear in a variable definition context. */
if (gfc_check_vardef_context (assoc->target, pointer, false, NULL)
== FAILURE)
{
if (context)
gfc_error ("Associate-name '%s' can not appear in a variable"
" definition context (%s) at %L because its target"
" at %L can not, either",
name, context, &e->where,
&assoc->target->where);
return FAILURE;
}
}
return SUCCESS;
}