/*

Copyright (C) 2008-2012 Jaroslav Hajek

This file is part of Octave.

Octave 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 of the License, or (at your
option) any later version.

Octave 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 Octave; see the file COPYING.  If not, see
<http://www.gnu.org/licenses/>.

*/

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

#include "error.h"
#include "oct-obj.h"
#include "ov.h"
#include "pt-cbinop.h"
#include "pt-bp.h"
#include "pt-unop.h"
#include "pt-walk.h"

// If a tree expression is a transpose or hermitian transpose, return
// the argument and corresponding operator.

static octave_value::unary_op
strip_trans_herm (tree_expression *&exp)
{
  if (exp->is_unary_expression ())
    {
      tree_unary_expression *uexp =
        dynamic_cast<tree_unary_expression *> (exp);

      octave_value::unary_op op = uexp->op_type ();

      if (op == octave_value::op_transpose
          || op == octave_value::op_hermitian)
        exp = uexp->operand ();
      else
        op = octave_value::unknown_unary_op;

      return op;
    }
  else
    return octave_value::unknown_unary_op;
}

static octave_value::unary_op
strip_not (tree_expression *&exp)
{
  if (exp->is_unary_expression ())
    {
      tree_unary_expression *uexp =
        dynamic_cast<tree_unary_expression *> (exp);

      octave_value::unary_op op = uexp->op_type ();

      if (op == octave_value::op_not)
        exp = uexp->operand ();
      else
        op = octave_value::unknown_unary_op;

      return op;
    }
  else
    return octave_value::unknown_unary_op;
}

// Possibly convert multiplication to trans_mul, mul_trans, herm_mul,
// or mul_herm.

static octave_value::compound_binary_op
simplify_mul_op (tree_expression *&a, tree_expression *&b)
{
  octave_value::compound_binary_op retop
    = octave_value::unknown_compound_binary_op;

  octave_value::unary_op opa = strip_trans_herm (a);

  if (opa == octave_value::op_hermitian)
    retop = octave_value::op_herm_mul;
  else if (opa == octave_value::op_transpose)
    retop = octave_value::op_trans_mul;
  else
    {
      octave_value::unary_op opb = strip_trans_herm (b);

      if (opb == octave_value::op_hermitian)
        retop = octave_value::op_mul_herm;
      else if (opb == octave_value::op_transpose)
        retop = octave_value::op_mul_trans;
    }

  return retop;
}

// Possibly convert left division to trans_ldiv or herm_ldiv.

static octave_value::compound_binary_op
simplify_ldiv_op (tree_expression *&a, tree_expression *&)
{
  octave_value::compound_binary_op retop
    = octave_value::unknown_compound_binary_op;

  octave_value::unary_op opa = strip_trans_herm (a);

  if (opa == octave_value::op_hermitian)
    retop = octave_value::op_herm_ldiv;
  else if (opa == octave_value::op_transpose)
    retop = octave_value::op_trans_ldiv;

  return retop;
}

// Possibly contract and/or with negation.

static octave_value::compound_binary_op
simplify_and_or_op (tree_expression *&a, tree_expression *&b, octave_value::binary_op op)
{
  octave_value::compound_binary_op retop
    = octave_value::unknown_compound_binary_op;

  octave_value::unary_op opa = strip_not (a);

  if (opa == octave_value::op_not)
    {
      if (op == octave_value::op_el_and)
        retop = octave_value::op_el_not_and;
      else if (op == octave_value::op_el_or)
        retop = octave_value::op_el_not_or;
    }
  else
    {
      octave_value::unary_op opb = strip_not (b);

      if (opb == octave_value::op_not)
        {
          if (op == octave_value::op_el_and)
            retop = octave_value::op_el_and_not;
          else if (op == octave_value::op_el_or)
            retop = octave_value::op_el_or_not;
        }
    }

  return retop;
}

tree_binary_expression *
maybe_compound_binary_expression (tree_expression *a, tree_expression *b,
                                  int l, int c, octave_value::binary_op t)
{
  tree_expression *ca = a, *cb = b;
  octave_value::compound_binary_op ct;

  switch (t)
    {
    case octave_value::op_mul:
      ct = simplify_mul_op (ca, cb);
      break;

    case octave_value::op_ldiv:
      ct = simplify_ldiv_op (ca, cb);
      break;

    case octave_value::op_el_and:
    case octave_value::op_el_or:
      ct = simplify_and_or_op (ca, cb, t);
      break;

    default:
      ct = octave_value::unknown_compound_binary_op;
      break;
    }

  tree_binary_expression *ret = (ct == octave_value::unknown_compound_binary_op)
    ? new tree_binary_expression (a, b, l, c, t)
    : new tree_compound_binary_expression (a, b, l, c, t, ca, cb, ct);

  return ret;
}

octave_value
tree_compound_binary_expression::rvalue1 (int)
{
  octave_value retval;

  if (error_state)
    return retval;

  if (op_lhs)
    {
      octave_value a = op_lhs->rvalue1 ();

      if (! error_state && a.is_defined () && op_rhs)
        {
          octave_value b = op_rhs->rvalue1 ();

          if (! error_state && b.is_defined ())
            {
              retval = ::do_binary_op (etype, a, b);

              if (error_state)
                retval = octave_value ();
            }
        }
    }

  return retval;
}