Safe Numerics |
For purposes of exposition, we've divided the discussion of how to eliminate runtime penalties by the different approaches available. A realistic program could likely include all techniques mentioned above. Consider the following:
#include <stdexcept> #include <iostream> #include <boost/safe_numerics/safe_integer.hpp> #include <boost/safe_numerics/safe_integer_range.hpp> #include <boost/safe_numerics/automatic.hpp> #include <boost/safe_numerics/exception.hpp> #include "safe_format.hpp" // prints out range and value of any type using namespace boost::safe_numerics; using safe_t = safe_signed_range< -24, 82, automatic, loose_trap_policy >; // define variables used for input using input_safe_t = safe_signed_range< -24, 82, automatic, // we don't need automatic in this case loose_exception_policy // assignment of out of range value should throw >; // function arguments can never be outside of limits auto f(const safe_t & x, const safe_t & y){ auto z = x + y; // we know that this cannot fail std::cout << "z = " << safe_format(z) << std::endl; std::cout << "(x + y) = " << safe_format(x + y) << std::endl; std::cout << "(x - y) = " << safe_format(x - y) << std::endl; return z; } int main(int argc, const char * argv[]){ std::cout << "example 84:\n"; input_safe_t x, y; try{ std::cout << "type in values in format x y:" << std::flush; std::cin >> x >> y; // read varibles, maybe throw exception } catch(const std::exception & e){ // none of the above should trap. Mark failure if they do std::cout << e.what() << std::endl; return 1; } std::cout << "x" << safe_format(x) << std::endl; std::cout << "y" << safe_format(y) << std::endl; std::cout << safe_format(f(x, y)) << std::endl; return 0; }
As before, we define a type safe_t
to reflect our
view of legal values for this program. This uses the automatic
type promotion policy as well as the loose_trap_policy
exception policy to enforce elimination of runtime penalties.
The function f
accepts only arguments of type
safe_t
so there is no need to check the input values.
This performs the functionality of programming by contract with no
runtime cost.
In addition, we define input_safe_t
to be used
when reading variables from the program console. Clearly, these can
only be checked at runtime so they use the throw_exception policy.
When variables are read from the console they are checked for legal
values. We need no ad hoc code to do this, as these types are
guaranteed to contain legal values and will throw an exception when
this guarantee is violated. In other words, we automatically get
checking of input variables with no additional programming.
On calling of the function f
, arguments of type
input_safe_t
are converted to values of type
safe_t
. In this particular example, it can be
determined at compile time that construction of an instance of a
safe_t
from an input_safe_t
can never
fail. Hence, no try/catch
block is necessary. The usage
of the loose_trap_policy
policy for safe_t
types guarantees this to be true at
compile time.
Here is the output from the program when values 12 and 32 are input from the console:
example 84: type in values in format x y:33 45 x<signed char>[-24,82] = 33 y<signed char>[-24,82] = 45 z = <short>[-48,164] = 78 (x + y) = <short>[-48,164] = 78 (x - y) = <signed char>[-106,106] = -12 <short>[-48,164] = 78