In my free time I like polishing my algorithm / programming skills (well, my skills suck and I try to improve them) by solving problems on pages like topcoder.com or uva.onlinejudge.com. Usually I can write and code correct algorithm for simpler problems - I understand most of the basic concepts regarding things like recursion or graphs.
The problem is, that most of the time, I fail at solving harder problems. As for now, I stumbled across this one (on spoj.pl):
Little Johnny is playing with his small magical stamp, trying to draw a bunny on a piece of paper that is a square k by k divided into unit squares with side 1. Johnny’s stamp is a square with side 3 and consists of smaller squares with side 1. Exactly two of these squares are protuberant. Moreover, both protuberant squares are in the same row or in the same column. If Johnny wants to draw pictures using this stamp, he presses it to the piece of paper in such a way that its protuberant squares exactly match some squares of the piece of paper. If some protuberant square touches the piece of paper, the touched square on the piece of paper changes its color — from black to white or from white to black. The small stamp may lay partially outside the piece of paper, but the protuberant squares always have to lay inside. The stamp can be shifted in any way, but it cannot be rotated.
In the beginning the piece of paper is whole white. The bunny consists of some number of squares that are black (all the remaining ones have to be white). Johnny tried to draw the bunny with his small stamp for quite a long time, but he did not succeed (this does not necessarily mean that the bunny cannot be drawn, but only that it is very difficult to draw pictures on such a large piece of paper using such a small stamp!). So he asked his older brother, big John, for help.
Big John can help little Johnny by giving him his big magical stamp. The big stamp has size s by s and has an arbitrary number of protuberant squares (these squares do not necessarily need to be located in the same row or column). This stamp works just like the small stamp, but enforces one additional constraint — it can only be pressed at the piece of paper if it lies totally inside the piece of paper.
Before big John gives little Johnny his big stamp, he would like to make sure that the stamps used together are sufficient to draw the bunny. He asked you for help in determining that. Input
The first line of the standard input contains one integer t (1 ≤ t ≤ 10) denoting the number of test cases.
A description of a single test case starts with a line with two integers s and k (1 ≤ s ≤ k ≤ 1000, 1 ≤ s ≤ 200) separated by a single space. They denote the size of big John’s stamp and the size of the piece of paper.
The following three lines contain a description of the little Johnny’s stamp. Each of these lines contains three characters 0 or 1. Such a description shows how does a white piece of paper look like after pressing the small stamp: 0 represents a white square, and 1 — a black square. Exactly two characters in these three lines are ones and are both located either in the same row or in the same column. Please note that such description does not illustrate the design of the stamp itself — the stamp is symmetric to the figure drawn by it on the piece of paper.
The following s lines contain a description of the big John’s stamp in a similar format; this description may, however, contain an arbitrary number of ones. The following k lines describe the bunny, in the same format as the one used in the descriptions of stamps. A one represents a black square, whereas a zero — a white square.
For each test case write out to the standard output a single line with a word "YES" (without quotation marks) or "NO", depending on whether the bunny from the test case can be drawn using the stamps from the test case (together).
For the input data:
2 3 8 010 000 010 000 010 011 01100000 00100000 00010000 00001100 00011110 10111100 01111100 01111110 5 10 001 001 000 00000 10100 00001 00001 00100 0011110000 0000111000 0010011100 0111001110 1110000000 1101001000 1000001100 0110110110 0001001000 0000110000
the correct output is:
The trick is, that the fact that I can code simple solutions, doesn't mean, that I can code the hard ones. It is similar to the fact, that in some games, after reaching certain level, killing weak enemies doesn't give you any(or very low amounts) experience.
I don't want any solutions nor ready algorithms - but can I ask for some guidelines?
What is a correct way of thinking when trying to solve this kind of problems (or this specific one)?