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/* Simplify intrinsic functions at compile-time.

   Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009,

   2010, 2011 Free Software Foundation, Inc.

   Contributed by Andy Vaught & Katherine Holcomb

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

<http://www.gnu.org/licenses/>.  */

#include "config.h"

#include "system.h"

#include "flags.h"

#include "gfortran.h"

#include "arith.h"

#include "intrinsic.h"

#include "target-memory.h"

#include "constructor.h"

#include "version.h"  /* For version_string.  */

gfc_expr gfc_bad_expr;

/* Note that 'simplification' is not just transforming expressions.

   For functions that are not simplified at compile time, range

   checking is done if possible.

   The return convention is that each simplification function returns:

     A new expression node corresponding to the simplified arguments.

     The original arguments are destroyed by the caller, and must not

     be a part of the new expression.

     NULL pointer indicating that no simplification was possible and

     the original expression should remain intact.

     An expression pointer to gfc_bad_expr (a static placeholder)

     indicating that some error has prevented simplification.  The

     error is generated within the function and should be propagated

     upwards

   By the time a simplification function gets control, it has been

   decided that the function call is really supposed to be the

   intrinsic.  No type checking is strictly necessary, since only

   valid types will be passed on.  On the other hand, a simplification

   subroutine may have to look at the type of an argument as part of

   its processing.

   Array arguments are only passed to these subroutines that implement

   the simplification of transformational intrinsics.

   The functions in this file don't have much comment with them, but

   everything is reasonably straight-forward.  The Standard, chapter 13

   is the best comment you'll find for this file anyway.  */

/* Range checks an expression node.  If all goes well, returns the

   node, otherwise returns &gfc_bad_expr and frees the node.  */

static gfc_expr *

range_check (gfc_expr *result, const char *name)

{

  if (result == NULL)

    return &gfc_bad_expr;

  if (result->expr_type != EXPR_CONSTANT)

    return result;

  switch (gfc_range_check (result))

    {

      case ARITH_OK:

        return result;

      case ARITH_OVERFLOW:

        gfc_error ("Result of %s overflows its kind at %L", name,

                   &result->where);

        break;

      case ARITH_UNDERFLOW:

        gfc_error ("Result of %s underflows its kind at %L", name,

                   &result->where);

        break;

      case ARITH_NAN:

        gfc_error ("Result of %s is NaN at %L", name, &result->where);

        break;

      default:

        gfc_error ("Result of %s gives range error for its kind at %L", name,

                   &result->where);

        break;

    }

  gfc_free_expr (result);

  return &gfc_bad_expr;

}

/* A helper function that gets an optional and possibly missing

   kind parameter.  Returns the kind, -1 if something went wrong.  */

static int

get_kind (bt type, gfc_expr *k, const char *name, int default_kind)

{

  int kind;

  if (k == NULL)

    return default_kind;

  if (k->expr_type != EXPR_CONSTANT)

    {

      gfc_error ("KIND parameter of %s at %L must be an initialization "

                 "expression", name, &k->where);

      return -1;

    }

  if (gfc_extract_int (k, &kind) != NULL

      || gfc_validate_kind (type, kind, true) < 0)

    {

      gfc_error ("Invalid KIND parameter of %s at %L", name, &k->where);

      return -1;

    }

  return kind;

}

/* Converts an mpz_t signed variable into an unsigned one, assuming

   two's complement representations and a binary width of bitsize.

   The conversion is a no-op unless x is negative; otherwise, it can

   be accomplished by masking out the high bits.  */

static void

convert_mpz_to_unsigned (mpz_t x, int bitsize)

{

  mpz_t mask;

  if (mpz_sgn (x) < 0)

    {

      /* Confirm that no bits above the signed range are unset.  */

      gcc_assert (mpz_scan0 (x, bitsize-1) == ULONG_MAX);

      mpz_init_set_ui (mask, 1);

      mpz_mul_2exp (mask, mask, bitsize);

      mpz_sub_ui (mask, mask, 1);

      mpz_and (x, x, mask);

      mpz_clear (mask);

    }

  else

    {

      /* Confirm that no bits above the signed range are set.  */

      gcc_assert (mpz_scan1 (x, bitsize-1) == ULONG_MAX);

    }

}

/* Converts an mpz_t unsigned variable into a signed one, assuming

   two's complement representations and a binary width of bitsize.

   If the bitsize-1 bit is set, this is taken as a sign bit and

   the number is converted to the corresponding negative number.  */

static void

convert_mpz_to_signed (mpz_t x, int bitsize)

{

  mpz_t mask;

  /* Confirm that no bits above the unsigned range are set.  */

  gcc_assert (mpz_scan1 (x, bitsize) == ULONG_MAX);

  if (mpz_tstbit (x, bitsize - 1) == 1)

    {

      mpz_init_set_ui (mask, 1);

      mpz_mul_2exp (mask, mask, bitsize);

      mpz_sub_ui (mask, mask, 1);

      /* We negate the number by hand, zeroing the high bits, that is

         make it the corresponding positive number, and then have it

         negated by GMP, giving the correct representation of the

         negative number.  */

      mpz_com (x, x);

      mpz_add_ui (x, x, 1);

      mpz_and (x, x, mask);

      mpz_neg (x, x);

      mpz_clear (mask);

    }

}

/* In-place convert BOZ to REAL of the specified kind.  */

static gfc_expr *

convert_boz (gfc_expr *x, int kind)

{

  if (x && x->ts.type == BT_INTEGER && x->is_boz)

    {

      gfc_typespec ts;

      gfc_clear_ts (&ts);

      ts.type = BT_REAL;

      ts.kind = kind;

      if (!gfc_convert_boz (x, &ts))

        return &gfc_bad_expr;

    }

  return x;

}

/* Test that the expression is an constant array.  */

static bool

is_constant_array_expr (gfc_expr *e)

{

  gfc_constructor *c;

  if (e == NULL)

    return true;

  if (e->expr_type != EXPR_ARRAY || !gfc_is_constant_expr (e))

    return false;

  for (c = gfc_constructor_first (e->value.constructor);

       c; c = gfc_constructor_next (c))

    if (c->expr->expr_type != EXPR_CONSTANT

          && c->expr->expr_type != EXPR_STRUCTURE)

      return false;

  return true;

}

/* Initialize a transformational result expression with a given value.  */

static void

init_result_expr (gfc_expr *e, int init, gfc_expr *array)

{

  if (e && e->expr_type == EXPR_ARRAY)

    {

      gfc_constructor *ctor = gfc_constructor_first (e->value.constructor);

      while (ctor)

        {

          init_result_expr (ctor->expr, init, array);

          ctor = gfc_constructor_next (ctor);

        }

    }

  else if (e && e->expr_type == EXPR_CONSTANT)

    {

      int i = gfc_validate_kind (e->ts.type, e->ts.kind, false);

      int length;

      gfc_char_t *string;

      switch (e->ts.type)

        {

          case BT_LOGICAL:

            e->value.logical = (init ? 1 : 0);

            break;

          case BT_INTEGER:

            if (init == INT_MIN)

              mpz_set (e->value.integer, gfc_integer_kinds[i].min_int);

            else if (init == INT_MAX)

              mpz_set (e->value.integer, gfc_integer_kinds[i].huge);

            else

              mpz_set_si (e->value.integer, init);

            break;

          case BT_REAL:

            if (init == INT_MIN)

              {

                mpfr_set (e->value.real, gfc_real_kinds[i].huge, GFC_RND_MODE);

                mpfr_neg (e->value.real, e->value.real, GFC_RND_MODE);

              }

            else if (init == INT_MAX)

              mpfr_set (e->value.real, gfc_real_kinds[i].huge, GFC_RND_MODE);

            else

              mpfr_set_si (e->value.real, init, GFC_RND_MODE);

            break;

          case BT_COMPLEX:

            mpc_set_si (e->value.complex, init, GFC_MPC_RND_MODE);

            break;

          case BT_CHARACTER:

            if (init == INT_MIN)

              {

                gfc_expr *len = gfc_simplify_len (array, NULL);

                gfc_extract_int (len, &length);

                string = gfc_get_wide_string (length + 1);

                gfc_wide_memset (string, 0, length);

              }

            else if (init == INT_MAX)

              {

                gfc_expr *len = gfc_simplify_len (array, NULL);

                gfc_extract_int (len, &length);

                string = gfc_get_wide_string (length + 1);

                gfc_wide_memset (string, 255, length);

              }

            else

              {

                length = 0;

                string = gfc_get_wide_string (1);

              }

            string[length] = '\0';

            e->value.character.length = length;

            e->value.character.string = string;

            break;

          default:

            gcc_unreachable();

        }

    }

  else

    gcc_unreachable();

}

/* Helper function for gfc_simplify_dot_product() and gfc_simplify_matmul.  */

static gfc_expr *

compute_dot_product (gfc_expr *matrix_a, int stride_a, int offset_a,

                     gfc_expr *matrix_b, int stride_b, int offset_b)

{

  gfc_expr *result, *a, *b;

  result = gfc_get_constant_expr (matrix_a->ts.type, matrix_a->ts.kind,

                                  &matrix_a->where);

  init_result_expr (result, 0, NULL);

  a = gfc_constructor_lookup_expr (matrix_a->value.constructor, offset_a);

  b = gfc_constructor_lookup_expr (matrix_b->value.constructor, offset_b);

  while (a && b)

    {

      /* Copying of expressions is required as operands are free'd

         by the gfc_arith routines.  */

      switch (result->ts.type)

        {

          case BT_LOGICAL:

            result = gfc_or (result,

                             gfc_and (gfc_copy_expr (a),

                                      gfc_copy_expr (b)));

            break;

          case BT_INTEGER:

          case BT_REAL:

          case BT_COMPLEX:

            result = gfc_add (result,

                              gfc_multiply (gfc_copy_expr (a),

                                            gfc_copy_expr (b)));

            break;

          default:

            gcc_unreachable();

        }

      offset_a += stride_a;

      a = gfc_constructor_lookup_expr (matrix_a->value.constructor, offset_a);

      offset_b += stride_b;

      b = gfc_constructor_lookup_expr (matrix_b->value.constructor, offset_b);

    }

  return result;

}

/* Build a result expression for transformational intrinsics,

   depending on DIM. */

static gfc_expr *

transformational_result (gfc_expr *array, gfc_expr *dim, bt type,

                         int kind, locus* where)

{

  gfc_expr *result;

  int i, nelem;

  if (!dim || array->rank == 1)

    return gfc_get_constant_expr (type, kind, where);

  result = gfc_get_array_expr (type, kind, where);

  result->shape = gfc_copy_shape_excluding (array->shape, array->rank, dim);

  result->rank = array->rank - 1;

  /* gfc_array_size() would count the number of elements in the constructor,

     we have not built those yet.  */

  nelem = 1;

  for  (i = 0; i < result->rank; ++i)

    nelem *= mpz_get_ui (result->shape[i]);

  for (i = 0; i < nelem; ++i)

    {

      gfc_constructor_append_expr (&result->value.constructor,

                                   gfc_get_constant_expr (type, kind, where),

                                   NULL);

    }

  return result;

}

typedef gfc_expr* (*transformational_op)(gfc_expr*, gfc_expr*);

/* Wrapper function, implements 'op1 += 1'. Only called if MASK

   of COUNT intrinsic is .TRUE..

   Interface and implimentation mimics arith functions as

   gfc_add, gfc_multiply, etc.  */

static gfc_expr* gfc_count (gfc_expr *op1, gfc_expr *op2)

{

  gfc_expr *result;

  gcc_assert (op1->ts.type == BT_INTEGER);

  gcc_assert (op2->ts.type == BT_LOGICAL);

  gcc_assert (op2->value.logical);

  result = gfc_copy_expr (op1);

  mpz_add_ui (result->value.integer, result->value.integer, 1);

  gfc_free_expr (op1);

  gfc_free_expr (op2);

  return result;

}

/* Transforms an ARRAY with operation OP, according to MASK, to a

   scalar RESULT. E.g. called if

     REAL, PARAMETER :: array(n, m) = ...

     REAL, PARAMETER :: s = SUM(array)

  where OP == gfc_add().  */

static gfc_expr *

simplify_transformation_to_scalar (gfc_expr *result, gfc_expr *array, gfc_expr *mask,

                                   transformational_op op)

{

  gfc_expr *a, *m;

  gfc_constructor *array_ctor, *mask_ctor;

  /* Shortcut for constant .FALSE. MASK.  */

  if (mask

      && mask->expr_type == EXPR_CONSTANT

      && !mask->value.logical)

    return result;

  array_ctor = gfc_constructor_first (array->value.constructor);

  mask_ctor = NULL;

  if (mask && mask->expr_type == EXPR_ARRAY)

    mask_ctor = gfc_constructor_first (mask->value.constructor);

  while (array_ctor)

    {

      a = array_ctor->expr;

      array_ctor = gfc_constructor_next (array_ctor);

      /* A constant MASK equals .TRUE. here and can be ignored.  */

      if (mask_ctor)

        {

          m = mask_ctor->expr;

          mask_ctor = gfc_constructor_next (mask_ctor);

          if (!m->value.logical)

            continue;

        }

      result = op (result, gfc_copy_expr (a));

    }

  return result;

}

/* Transforms an ARRAY with operation OP, according to MASK, to an

   array RESULT. E.g. called if

     REAL, PARAMETER :: array(n, m) = ...

     REAL, PARAMETER :: s(n) = PROD(array, DIM=1)

  where OP == gfc_multiply(). The result might be post processed using post_op. */

static gfc_expr *

simplify_transformation_to_array (gfc_expr *result, gfc_expr *array, gfc_expr *dim,

                                  gfc_expr *mask, transformational_op op,

                                  transformational_op post_op)

{

  mpz_t size;

  int done, i, n, arraysize, resultsize, dim_index, dim_extent, dim_stride;

  gfc_expr **arrayvec, **resultvec, **base, **src, **dest;

  gfc_constructor *array_ctor, *mask_ctor, *result_ctor;

  int count[GFC_MAX_DIMENSIONS], extent[GFC_MAX_DIMENSIONS],

      sstride[GFC_MAX_DIMENSIONS], dstride[GFC_MAX_DIMENSIONS],

      tmpstride[GFC_MAX_DIMENSIONS];

  /* Shortcut for constant .FALSE. MASK.  */

  if (mask

      && mask->expr_type == EXPR_CONSTANT

      && !mask->value.logical)

    return result;

  /* Build an indexed table for array element expressions to minimize

     linked-list traversal. Masked elements are set to NULL.  */

  gfc_array_size (array, &size);

  arraysize = mpz_get_ui (size);

  mpz_clear (size);

  arrayvec = XCNEWVEC (gfc_expr*, arraysize);

  array_ctor = gfc_constructor_first (array->value.constructor);

  mask_ctor = NULL;

  if (mask && mask->expr_type == EXPR_ARRAY)

    mask_ctor = gfc_constructor_first (mask->value.constructor);

  for (i = 0; i < arraysize; ++i)

    {

      arrayvec[i] = array_ctor->expr;

      array_ctor = gfc_constructor_next (array_ctor);

      if (mask_ctor)

        {

          if (!mask_ctor->expr->value.logical)

            arrayvec[i] = NULL;

          mask_ctor = gfc_constructor_next (mask_ctor);

        }

    }

  /* Same for the result expression.  */

  gfc_array_size (result, &size);

  resultsize = mpz_get_ui (size);

  mpz_clear (size);

  resultvec = XCNEWVEC (gfc_expr*, resultsize);

  result_ctor = gfc_constructor_first (result->value.constructor);

  for (i = 0; i < resultsize; ++i)

    {

      resultvec[i] = result_ctor->expr;

      result_ctor = gfc_constructor_next (result_ctor);

    }

  gfc_extract_int (dim, &dim_index);

  dim_index -= 1;               /* zero-base index */

  dim_extent = 0;

  dim_stride = 0;

  for (i = 0, n = 0; i < array->rank; ++i)

    {

      count[i] = 0;

      tmpstride[i] = (i == 0) ? 1 : tmpstride[i-1] * mpz_get_si (array->shape[i-1]);

      if (i == dim_index)

        {

          dim_extent = mpz_get_si (array->shape[i]);

          dim_stride = tmpstride[i];

          continue;

        }

      extent[n] = mpz_get_si (array->shape[i]);

      sstride[n] = tmpstride[i];

      dstride[n] = (n == 0) ? 1 : dstride[n-1] * extent[n-1];

      n += 1;

    }

  done = false;

  base = arrayvec;

  dest = resultvec;

  while (!done)

    {

      for (src = base, n = 0; n < dim_extent; src += dim_stride, ++n)

        if (*src)

          *dest = op (*dest, gfc_copy_expr (*src));

      count[0]++;

      base += sstride[0];

      dest += dstride[0];

      n = 0;

      while (!done && count[n] == extent[n])

        {

          count[n] = 0;

          base -= sstride[n] * extent[n];

          dest -= dstride[n] * extent[n];

          n++;

          if (n < result->rank)

            {

              count [n]++;

              base += sstride[n];

              dest += dstride[n];

            }

          else

            done = true;

       }

    }

  /* Place updated expression in result constructor.  */

  result_ctor = gfc_constructor_first (result->value.constructor);

  for (i = 0; i < resultsize; ++i)

    {

      if (post_op)

        result_ctor->expr = post_op (result_ctor->expr, resultvec[i]);

      else

        result_ctor->expr = resultvec[i];

      result_ctor = gfc_constructor_next (result_ctor);

    }

  free (arrayvec);

  free (resultvec);

  return result;

}

static gfc_expr *

simplify_transformation (gfc_expr *array, gfc_expr *dim, gfc_expr *mask,

                         int init_val, transformational_op op)

{

  gfc_expr *result;

  if (!is_constant_array_expr (array)

      || !gfc_is_constant_expr (dim))

    return NULL;

  if (mask

      && !is_constant_array_expr (mask)

      && mask->expr_type != EXPR_CONSTANT)

    return NULL;

  result = transformational_result (array, dim, array->ts.type,

                                    array->ts.kind, &array->where);

  init_result_expr (result, init_val, NULL);

  return !dim || array->rank == 1 ?

    simplify_transformation_to_scalar (result, array, mask, op) :

    simplify_transformation_to_array (result, array, dim, mask, op, NULL);

}

/********************** Simplification functions *****************************/

gfc_expr *

gfc_simplify_abs (gfc_expr *e)

{

  gfc_expr *result;

  if (e->expr_type != EXPR_CONSTANT)

    return NULL;

  switch (e->ts.type)

    {

      case BT_INTEGER:

        result = gfc_get_constant_expr (BT_INTEGER, e->ts.kind, &e->where);

        mpz_abs (result->value.integer, e->value.integer);

        return range_check (result, "IABS");

      case BT_REAL:

        result = gfc_get_constant_expr (BT_REAL, e->ts.kind, &e->where);

        mpfr_abs (result->value.real, e->value.real, GFC_RND_MODE);

        return range_check (result, "ABS");

      case BT_COMPLEX:

        gfc_set_model_kind (e->ts.kind);

        result = gfc_get_constant_expr (BT_REAL, e->ts.kind, &e->where);

        mpc_abs (result->value.real, e->value.complex, GFC_RND_MODE);

        return range_check (result, "CABS");

      default:

        gfc_internal_error ("gfc_simplify_abs(): Bad type");

    }

}

static gfc_expr *