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Summary: We explore some of the kinds of numbers and procedures that Scheme (well, the implementation of Scheme that MediaScript uses) supports.

As you may recall, the reading on documenting procedures introduced a variety of procedures that compute grades. The documentation for this procedure, while a bit long, seems quite straightforward. The first implementation, which simply computed the average, looks like this: The second implementation, which dropped the lowest grade and doubled the highest grade, looks like this. a. Check that the second version of compute-grade computes a grade using the strategy specified in the narrative. (That is, that it drops the lowest grade and doubles the highest grade.) You might, for example, use grades of 0, 50, 50, 50, 50, and 80. b. Write a new version of compute-grade that drops both the lowest and highest grade. c. Does this new version correspond to the documentation given in the reading? Why or why not? d. Suppose someone wrote a new version of compute-grade that returns the average of the homework assignments, with an additional one point of extra credit for each assignment over 80. Would this version correspond to the documentation? Why or why not?

Consider the following procedure. a. Suppose we always use 0 for lower and 100 for upper. What value do you expect bound to return when val is 10? 120? 2386? -42? b. Check your answers experimentally. c. Explain why this procedure is called bound.

Consider the following procedure. a. Create an image on which you can test image-bounded-select-ellipse!. b. Identify at least one set of values (left, top, width, and height) for which image-bounded-select-ellipse! behaves the same as image-select-ellipse!. c. Identify at least one set of values (left, top, width, and height) for which image-bounded-select-ellipse! behaves differently than image-select-ellipse!. d. Explain in English what image-bounded-select-ellipse! does.

As the reading suggests, the modulo procedure computes a value much like the remainder, except that the result is always the same sign as the second parameter, called the modulus. (So, when we use a positive modulus, we get a positive result.) The reading also suggests that modulo provides an interesting alternative to using max and min to limit the values of functions. a. What value do you expect each of the following to produce? > (modulo 254 256) > (modulo 256 256) > (modulo 257 256) > (modulo 515 256) > (modulo 2567 256) > (modulo 0 256) > (modulo -256 256) > (modulo -257 256) > (modulo -255 256) > (modulo -1 256) b. Check your answers experimentally, one at a time. If you find that any of your answers don't match what Scheme does, try to figure out why (asking your professor or a tutor if you need help), and then rethink your remaining answers before checking them experimentally.

As the reading on numbers suggests, Scheme provides four functions that convert real numbers to nearby integers: floor, ceiling, round, and truncate. The reading also claims that there are differences between all four. To the best of your ability, figure out what each does, and what distinguishes it from the other three. In your tests, you should try both positive and negative numbers, numbers close to integers and numbers far from integers. (Numbers whose fractional part is 0.5 are about as far from an integer as any real number can be.) Once you have figured out answers, check the notes on this problem.

As you may recall from an earlier exercise, it is sometimes useful to be able to count the value 1 for a high score and a value 0 for a lower score. (For convenience, we'll say that a score of 80 or above is high and a score below 80 is low. We'll also assume that all scores are between 0 and 100.) Most of us would give the instructions for converting score to count as something like If the score is 80 or above, the count is 1; otherwise, the count is 0. However, you have yet to learn to write conditionals (expressions that make choices). Are you doomed? Certainly not. One of the four functions you've just learned, in conjunction with some other arithmetic operations would allow us to create counts for scores. (Yes, we're being deliberately vague. Part of the goal of this problem is for you to think about approaches.) a. Write a procedure, (grade-count grade) that, given a grade between 0 and 100, returns 0 if the number is less than 80 and 1 if the grade is 80 or above. If the grade is not in the range [0..100], this procedure can do anything. You may return exact or inexact numbers. For example, > (grade-count 80) 1 > (grade-count 79) 0 > (grade-count 81) 1 > (grade-count 10) 0 > (grade-count 95) 1 > (grade-count 90.5) 1.0 > (grade-count 60.5) 0.0 b. Suppose we also wanted to support grades larger than 100, continuing our policy of any grade 80 or over gets 1. Will your code for part a work? If not, write a new version of grade-count that also works for numbers greater than 100. T > (grade-count 79) 0 > (grade-count 80) 1 > (grade-count 120) 1 > (grade-count 167) 1 > (grade-count 2009) 1 c. Suppose we also wanted to support negative grades. (Yes, there are teachers who give negative grades.) Will your code for part a or part b work? If not, write a new version of grade-count that also works for negative numbers.

If you have extra time left at the end of this lab, you might try the exploration below or you might try one of these problems.

You may recall that we have a number of mechanisms for rounding real numbers to integers. But what if we want to round not to an integer, but to only two digits after the decimal point? Scheme does not include a built-in operation for doing that kind of rounding. Nonetheless, it is fairly straightforward. Write a procedure, (round-to-hundredths r) that rounds r to the nearest hundredth. For example, > (round-to-hundredths 22.71256) 22.71 > (round-to-hundredths 10.7561) 10.76

As you may have noted, the procedure image-bounded-select-ellipse! converted an elliptical selection to one that had to start in the upper-left quadrant and had both height and width between 20 and 40. We might use modulo to achieve similar limits. Here's one attempt. a. Create a 200x200 image and call it canvas. b. What differences, if any, do you expect between the following three selection calls: > (image-select-ellipse! canvas REPLACE 10 10 30 30) > (image-bounded-select-ellipse! canvas REPLACE 10 10 30 30) > (image-strange-select-ellipse! canvas REPLACE 10 10 30 30) c. Check your answer experimentally. d. What differences, if any, do you expect between the following three selection calls: > (image-select-ellipse! canvas REPLACE 100 10 30 30) > (image-bounded-select-ellipse! canvas REPLACE 100 10 30 30) > (image-strange-select-ellipse! canvas REPLACE 100 10 30 30) e. Check your answer experimentally. f. What differences, if any, do you expect between the following three selection calls: > (image-select-ellipse! canvas REPLACE 10 10 60 5) > (image-bounded-select-ellipse! canvas REPLACE 10 10 60 5) > (image-strange-select-ellipse! canvas REPLACE 10 10 60 5) g. Check your answer experimentally.

In a problem above, you wrote a procedure that rounded a real number to two digits after the decimal place. While such rounding is useful, it is even more useful to let the client of your procedure choose how many digits after the decimal point to use. a. Write a procedure, (round-to r places), that rounds r to places places after the decimal point. As you write round-to, you may find the expt useful. (expt b p) computes bp. b. Try redefining round-to-hundredths in terms of round-to.

Here are the ways we tend to think of the four functions: (floor r) finds the largest integer less than or equal to r. Some would phrase this as floor rounds down. (ceiling r) finds the smallest integer greater than or equal to r. Some would phrase this as ceiling rounds up. (truncate r) removes the fractional portion of r, the portion after the decimal point. (round r) rounds r to the nearest integer. It rounds up if the decimal portion is greater than 0.5 and it rounds down if the decimal portion is less than 0.5. If the decimal portion equals 0.5, it rounds toward the even number. > (round 1.5) 2 > (round 2.5) 2 > (round 7.5) 8 > (round 8.5) 8 > (round -1.5) -2 > (round -2.5) -2 It's pretty clear that floor and ceiling differ - If r has a fractional component, then (floor r) is one less than (ceiling r). It's also pretty clear that round differs from all of them, since it can round in two different directions. We can also tell that truncate is different from ceiling, at least for positive numbers, because ceiling always rounds up, and removing the fractional portion of a positive number causes us to round down. So, how do truncate and floor differ? As the previous paragraph implies, they differ for negative numbers. When you remove the fractional component of a negative number, you effectively round up. (After all, -2 is bigger than -2.3.) However, floor always rounds down. Why does Scheme include so many ways to convert reals to integers? Because experience suggests that if you leave any of them out, some programmer will need that precise conversion. Return to the problem.