| Volume Number: | 10 | |||
| Issue Number: | 12 | |||
| Column Tag: | Programmer’s Challenge | |||
Programmer’s Challenge 
By Mike Scanlin, Mountain View, CA
Note: Source code files accompanying article are located on MacTech CD-ROM or source code disks.
The rules
Here’s how it works: Each month we present a different programming challenge here. First, you write some code that solves the challenge. Second, optimize your code (a lot). Then, submit your solution to MacTech Magazine. We choose a winner based on code correctness, speed, size and elegance (in that order of importance) as well as the postmark of the answer. In the event of multiple equally-desirable solutions, we’ll choose one winner at random (with honorable mention, but no prize, given to the runners up). The prize for each month’s best solution is $50 and a limited-edition “The Winner! MacTech Magazine Programming Challenge” T-shirt (not available in stores).
To help us make fair comparisons, all solutions must be in ANSI compatible C (e.g. don’t use Think’s Object extensions). Use only pure C code. We disqualify any entries with any assembly in them (except for challenges specifically stated to be in assembly). You may call any routine in the Macintosh toolbox (e.g., it doesn’t matter if you use NewPtr instead of malloc). We test entries with the FPU and 68020 flags turned off in THINK C. We time routines with the latest THINK C (with “ANSI Settings”, “Honor ‘register’ first”, and “Use Global Optimizer” turned on), so beware if you optimize for a different C compiler. Limit your code to 60 characters wide. This helps with e-mail gateways and page layout.
We publish the solution and winners for this month’s Programmers’ Challenge two months later. All submissions must be received by the 10th day of the month printed on the front of this issue.
Mark solutions “Attn: Programmers’ Challenge Solution” and send them via e-mail - Internet progchallenge@xplain.com, AppleLink MT.PROGCHAL, CompuServe 71552,174 and America Online MT PRGCHAL. Include the solution, all related files, and your contact info. If you send via snail mail, send a disk with those items on it; see “How to Contact Us” on p. 2.
MacTech Magazine reserves the right to publish any solution entered in the Programming Challenge of the Month. Authors grant MacTech Magazine the non-exclusive right to publish entries without limitation upon submission of each entry. Authors retain copyrights for the code.
Rubik’s Cube
There are several things I’m good at. Solving Rubik’s Cube isn’t one of them. One of my sadist friends gave me one last Christmas. I scramble it all the time and leave it on my desk at work. Then I watch in amazement as any one of several co-workers walks up to it and solves it within the amount of time it takes to ask “Mike, what’s the fastest way to do buffered file I/O?” It’s very frustrating.
This month’s challenge idea comes not only from my own inadequacy but also from Jim Lloyd (Mountain View, CA). The goal is to solve Rubik’s Cube.
The prototype of the function you write is:
/* 1 */ int SolveRubiksCube(cubePtr) RubiksCube*cubePtr;
Since I am so pathetic at solving the cube, I do not have enough insight to design an effective data structure to represent it. You get to define the RubiksCube typedef anyway you like.
Each call to SolveRubiksCube should make exactly one move. A move means turning any side any direction by 90 degrees. The function returns one of 3 values on each call to it:
/* 2 */ -1 illegal cube condition, can’t be solved 0 made a move, but not done yet 1 made the last move, it’s solved
Your routine will be called in a loop from my test bench something like this:
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/* 3 */
ScrambleCube(cubePtr);
do {
x = SolveRubiksCube(cubePtr);
} while (x == 0);
Minimizing the number of moves to solve the cube is not important. Minimizing the total time required to solve the cube is important. If your SolveRubiksCube routine needs to keep track of some kind of state info or cached solution info between calls to it then it may use static variables to do so (or, you could incorporate that info into the RubiksCube data structure).
It is not required to detect an illegal cube condition on the first call to SolveRubiksCube, just so long as it is detected eventually (i.e. don’t go into an infinite loop if someone removes a couple of squares from your cube and puts them back in such a way that it makes the cube unsolvable).
Because I will need to be able to watch your routine’s progress, you will need to write two conversion routines:
/* 4 */ void MikeCubeToRubiksCube(mikePtr, rubikPtr) MikeCube*mikePtr; RubiksCube*rubikPtr; void RubiksCubeToMikeCube(rubikPtr, mikePtr) RubiksCube*rubikPtr; MikeCube*mikePtr;
The purpose is to convert your cube from whatever data structure you come up with into something my test bench can understand. It only knows about MikeCubes:
/* 5 */
typedef struct CubeSide {
char littleSquare[3][3];
} CubeSide;
typedef struct MikeCube {
CubeSide face[6];
} MikeCube;
A cube has 6 CubeSides. If you look at a cube straight on then the indexes are: 0 = top, 1 = left side, 2 = front, 3 = right side, 4 = bottom, 5 = back. Within each CubeSide there is a 3x3 array of littleSquares (first index is row, second index is column). Each littleSquare is a number from 0 to 5, where each number represents one of the 6 colors that make up a cube.
So, a solved cube would have all 9 of the littleSquares for each side set to the same value. A solved cube that had the rightmost vertical column rotated counterclockwise 90 degrees would look like this:
005 005 005 111220333 111220333 111220333 442 442 442 554 554 554
The top part (the 005 lines) represent the top of the cube after the rotation. The 220 pieces are what you see on the front, the 442 lines are what you see on the bottom and the 554 pieces are what’s on the back. The value of mikePtr-> face[0]. littleSquare[1][2] is 5. The value of mikePtr->face[0].littleSquare[1][1] is 0 (the center square of the top).
Write to me if you have questions on this. Your conversion routines are not going to be part of your times so it doesn’t matter if they’re slow. Have fun.
Two Months Ago Winner
Based on the number of entries I received for the How Long Will It Take Challenge I would have to say that software time estimates are even more difficult than their well-deserved reputation implies. Either that or the typical Programmer Challenge entrant isn’t concerned with schedules (or, at least, this Challenge). In any case, congrats (and thanks) to Jeremy Vineyard (Lawrence, KS) for winning. I suppose the fact that he was the only person to enter helped his entry somewhat but there are signs of some careful thinking in his entry as well. (Although I must confess that I find the inclusion of a Jolt Cola parameter completely useless. Mountain Dew on the other hand...) This is Jeremy’s second 1st place showing (he also won the Insane Anglo Warlord challenge in February, 1993). Nice job!
Jeremy’s entry refers to a book by E. Barne called “Estimation of Time-Space Development Theorems” which I wasn’t, unfortunately, able to track down before my column deadline. Sounds like something to check out, though, if you’re involved with scheduling.
Here’s Jeremy’s winning solution:
Top 5 Excuses Why This Project Was Late:
1. “I though you said it was due NEXT month!”
2. The Product Manager quit after we missed the beta acceptance deadline.
3. Somebody activated the fire alarm while we were holding a brainstorming session, and all our ideas were lost.
4. QA didn’t keep us up to date on active bugs.
5. I just couldn’t wait to try out the new game of solitaire that came with System 7.5!
The skill of the product manager is the key to a successful product.
/* 6 */
enum {
// Manager ratings.
noManager = 0,
lazyManager = 1,
poorManager = 2,
okManager = 3,
motivatedManager = 4,
excellentManager = 5
};
enum {
// System versions.
system7 = 7,
system6 = 6,
system5 = 5,
system4 = 4,
system3 = 3,
system2 = 2,
system1 = 1
};
// It assumed that the better the manager is, the more lines
// the engineers will be motivated to write.
#define juniorLines(100 + (20 * manager))
#define seniorLines(200 + (25 * manager))
// Every large project will have an overhead for planning,
// designing, and preparing for development.
#define overhead (linesC / 5000)
// These ratios are based on Barne’s matrix equations
// related to the study of time-space software development
// theorems. (trust me!)
#define PPCNativeRatio (float) (1.75 - (.02 * powerMacs))
#define joltRatio(float) (.7)
#define systemSupportRatio(float) (7.0 / systemSupport)
// Here again,the manager can motivate both QA and UI
// people to be more productive.
#define qaRatio 1 - (.1 + (.01 * manager) * qaPeople)
#define uiRatio (float) ((1.2 - \
(.01 * manager)) * (seniorEng - uiPeople))
// Localization- a nightmare. Enough said.
#define localizedRatio (float) (1.35 * localized)
SoftwareTimeEstimate
A simplified algorithm that accurately calculates the time in calendar days for any Macintosh software product to be completed.
The complete algorithm and collection of equations can be found in E. Barne’s Estimation of Time-Space Development Theorems, published by Academic Press.
Implementation by Jeremy Vineyard, Lawrence, KS
/* 7 */
SoftwareTimeEstimate
unsigned short SoftwareTimeEstimate(linesC, seniorEng,
juniorEng, systemSupport, PPCNative, powerMacs, manager,
jolt, qaPeople, uiPeople, localized)
// Estimated # lines of source code in C.
unsigned long linesC;
// # of competent engineers with more than 5
// years experience.
unsigned short seniorEng;
// # of junior engineers with less than 2
// years experience.
unsigned short juniorEng;
// Earliest version of system software supported by
// product (1-7)
unsigned short systemSupport;
// TRUE if product will be PowerPC native.
Boolean PPCNative;
// # of PowerMacs available to developers (1-30).
unsigned short powerMacs;
// Rating of manager 1-5 (1 is poor, 5 is excellent)
// or 0 if none.
unsigned short manager;
// TRUE if company has steady supply of Jolt cola.
Boolean jolt;
// # of trained, in-house testers (most important).
unsigned short qaPeople;
// # of people responsible for making decisions about UI.
unsigned short uiPeople;
// # of Languages product must be localized to before
// shipping or 0 if none.
unsigned short localized;
{
float time, ratio;
short linesADay;
// Calculate the lines of source code that can be
// produced per day based upon the number of engineers
// working on the product.
// (Must have at least one engineer)
linesADay = (seniorEng * seniorLines)
+ (juniorEng * juniorLines);
// Estimate the # of days it will take to produce the
// specified amount of code.
time = (linesC / linesADay) + overhead;
// The farther backwards this product is compatible with
// system versions, the more time it will take to develop.
// systemSupport should be from 1 (System 1.0) to 7.
time *= systemSupportRatio;
// More development & QA time will need to be spent on
// a product that is PowerPC native. The more Power Macs
// that are available to developers, the faster the
// development & testing process will proceed.
if (PPCNative)
time *= PPCNativeRatio;
// o JOLT COLA! o
// o GIve the PRogramMeRS that EXtra ZING! to geT thEm o
// o MOTIVATED!! o
if (jolt)
time *= joltRatio;
// Quality assurance is one of the most important
// aspects of a product’s construction. Without it, the
// product will fail to reach the user base because of
// too many bugs. QA can never be overstaffed!
time *= qaRatio;
// User interface has a limited potential because people
// are likely to have very set opinions, and if there
// are too many UI people, it can kill a product. There
// should never be more UI personnel than engineers.
if (uiPeople > seniorEng)
time *= uiRatio;
// The more languages the product must be localized to
// before it can be shipped has a drastic effect on the
// development time.
if (localized)
time *= localizedRatio;
return (short) time;
}
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