Difference between revisions of "FormulaTestPoints"

Context("Numeric");
Context()->variables->set(x=>{limits=>[-1,1]});
$func = Compute("sqrt(x+1)");

## Alternately:
Context()->flags->set(limits=>[2,5]);
# $func = Compute("sqrt(x-1)");

## Or, setting the limits only for the given
##    formula, we don't need to reset the Context,
##    and just include
# $func = Compute("sqrt(x-1)");
# $func->{limits} = [2,5];

$gunc = Compute("sqrt(x^2 - 4)");
$gunc->{test_points} = [[-3],[-2],[2],[3],[4]];
#$gunc->{test_at} = [[-3],[-2],[2],[3],[4]];

We don't have to change anything in the documentation and tagging or initialization sections of the PG file. In the problem set-up, we can specify the limits on which all Formulas are evaluated by setting the limits for the variable in the problem (in this case, x) in the Context. Alternately, we can set the Context flag limits to set the limits on all variables in the Context, as shown in the commented-out line, or can set the limits for the formula itself, as in the second commented-out line. (Obviously, only one of these three is needed.)

It is also possible to specify the actual points on which the Formula will be evaluated. This is an attribute of the Formula itself; the call is shown for our formula $gunc. In this case there is only one variable, so we have only to specify a single value for each point where the function is to be evaluated. (Using test_at adds the specified points to those already chosen from the continuous domain while with test_points only the specified test points are used.) If the function were a function of two variables, then we might use something like $formula->{test_points} = [[-3,-2],[-2,0],[2,0],[3,2],[4,5]]. Note that the test points are given in alphabetical order by variable name! Thus, if the variables in the formula are specified as x and C, the test point [3,2] is C=3 and x=2.

Note: if the formula is a function of more than one variable and we're specifying limits in the formula, we need to specify the limits for all variables. Thus, we'd have something like $formula->{limits} = [[-1,1],[0,2]]. Again, the limits are specified for each variable in alphabetical order.

Also note that your test points must contain one value per variable, even if it doesn't appear in the formula; for instance, if $gunc is a function only of y, then you need to include values for x and y, not just y. The alternative is to use the command Context() -> variables -> are (y => 'Real') which will remove the (default) variable x from the problem.

If you are trying to set test points for a function you have added to the context (e.g., using parserFunction.pl) you should use the syntax $h->with(test_at=>[[1],[2]]) as in the following code snippet:

loadMacros("parserFunction.pl");

Context("Numeric");
parserFunction("m(x)" => "log(x/2)" );
$h = Formula("5 m(x)+2");
$answer = $h->with(test_at => [[1],[2]]);

If you want to add a variable n to the context that is only evaluated at integers, use integer limits and a resolution of 1 as in the following example:

Context()->variables->add(n => ['Real', limits=>[1,20], resolution=>1]);

BEGIN_TEXT
Enter \( $func \): \{ ans_rule(35) \}
$BR
Enter \( $gunc \): \{ ans_rule(35) \}
END_TEXT

The text portion of the file is the same as usual.

ANS( $func->cmp() );
ANS( $gunc->cmp() );

And the answer evaluation is as we'd expect.

  $func = "sqrt(x+1)";
  $gunc = "sqrt(x^2 - 4)";

We define the functions as expected in the problem set-up section of the file.

  BEGIN_TEXT
  Enter \( \sqrt{x+1} \): \{ ans_rule(35) \}
  $BR
  Enter \( \sqrt{x^2 - 4} \): 
  \{ ans_rule(35) \}
  END_TEXT

And the text portion of the file is similarly mundane.

  ANS(fun_cmp($func, limits=>[-1,1]));
  ANS(fun_cmp($gunc, test_points=>[-3,-2,2,3,4]));

The limits or test points are specified in the fun_cmp call. Note that we can use the short-hand [-3,-2,2,3,4] for the list of points when there is only one variable; in the case of multiple variables, we would have to specify a list of lists as we did above.