expr_ptr simplify_an_expression(expr_ptr& expr, bool& mod)
{
// expr->append_text(std::cout << "simplifying: ") << std::endl;
switch(expr->get_type())
{
case REAL : /* return simplify (Real {(real *) expr.release()}, mod); */ break;
case COMPLEX : /* return simplify (Complex {(complex *) expr.release()}, mod); */ break;
case MULT : return simplify_mult(Multiplication {(multiplication *) expr.release()}, mod);
case DIV : /* return simplify (Division {(division *) expr.release()}, mod); */ break;
case ADD : return simplify_add (Addition {(addition *) expr.release()}, mod);
case SUB : /* return simplify (Subtraction {(subtraction *) expr.release()}, mod); */ break;
case EXPO : /* return simplify (Exponent {(exponent *) expr.release()}, mod); */ break;
case NEGATE : return simplify_neg (Negation {(negation *) expr.release()}, mod);
case VARIABLE: /* return simplify (Variable {(variable *) expr.release()}, mod); */ break;
case LOG : /* return simplify (expr_ptr {(expression_raw *) expr.release()}, mod); */ break;
case INTERVAL: /* return simplify (expr_ptr {(expression_raw *) expr.release()}, mod); */ break;
case IEEE : /* return simplify (expr_ptr {(expression_raw *) expr.release()}, mod); */ break;
case ZERO : /* return expr_ptr{expr.release()}; */ break;
case UNITY : /* return expr_ptr{expr.release()}; */ break;
case ANYTHING: /* return expr_ptr{expr.release()}; */ break;
case NAN : /* return expr_ptr{expr.release()}; */ break;
case INFINITY: /* return expr_ptr{expr.release()}; */ break;
default:
trap("Unable to simplify expression of type: " + expr->get_text());
}
return expr_ptr{expr.release()};
}
expr_ptr recursive_apply(expr_ptr& expr, expr_ptr (simplifier)(expr_ptr& expr, bool&), bool& mod)
{
switch(expr->get_type())
{
case MULT : { binary*b=(binary*) expr.release(); expr = Binary{new multiplication{ recursive_apply(b->first, simplifier, mod), recursive_apply(b->second, simplifier, mod) }}; break; }
case DIV : { binary*b=(binary*) expr.release(); expr = Binary{new division { recursive_apply(b->first, simplifier, mod), recursive_apply(b->second, simplifier, mod) }}; break; }
case ADD : { binary*b=(binary*) expr.release(); expr = Binary{new addition { recursive_apply(b->first, simplifier, mod), recursive_apply(b->second, simplifier, mod) }}; break; }
case SUB : { binary*b=(binary*) expr.release(); expr = Binary{new subtraction { recursive_apply(b->first, simplifier, mod), recursive_apply(b->second, simplifier, mod) }}; break; }
case EXPO : { break; }
case LOG : { break; }
case NEGATE : { Negation n{(negation*) expr.release()}; expr = recursive_apply(n->orig, simplifier, mod); break; }
case VARIABLE : { break; }
case INTERVAL : { break; }
case IEEE : { break; }
case REAL : { break; }
case COMPLEX : { break; }
case ZERO : { break; }
case UNITY : { break; }
case ANYTHING : { break; }
case NAN : { break; }
case INFINITY : { break; }
default:
trap("Unable to simplify expression of type: " + expr->get_text());
}
return simplifier(expr, mod);
}