Day 3: Gear Ratios


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  • @sjmulder@lemmy.sdf.org
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    1 year ago

    Language: C

    Part 2 stumped me for a little bit, it wasn’t an obvious extension of part 1. Part 1 was about numbers (with one or more …) while part 2 worked from the symbols (with exactly two …). Going the other way would require more bookkeeping to avoid double counting.

    And for the implementation: if you loop over the grid and check surrounding cells for digits you’d have to account for a bunch of cases, e.g. NW/N or N/NE being part of the same number or NW and NE being part of separate numbers. And you’d have to parse the numbers again. But building a graph or reference list of some sort is both unergonomic with C and not necessarily any simpler.

    I ended up just writing out the cases, and honestly it didn’t turn out too bad.

    GitHub link

    Abridged code
    int main(int argc, char **argv)
    {
    	static char G[GSZ][GSZ];
    	static int N[GSZ][GSZ];
    	int p1=0,p2=0, h=0, x,y, dx,dy, n=0,sym=0,r;
    	
    	for (h=0; fgets(&G[h+1][1], GSZ-1, stdin); h++)
    		assert(h < GSZ);
    
    	/*
    	 * Pass 1: parse numbers and solve part 1. For every digit in
    	 * G, the full number it is part of is stored in N.
    	 */
    	for (y=1; y<=h; y++)
    	for (x=1; G[y][x]; x++)
    		if (isdigit(G[y][x])) {
    			n = n*10 + G[y][x]-'0';
    
    			for (dy=-1; dy<2; dy++)
    			for (dx=-1; dx<2; dx++)
    				sym = sym || (x && y &&
    				    G[y+dy][x+dx] != '.' &&
    				    ispunct(G[y+dy][x+dx]));
    		} else {
    			for (dx=-1; isdigit(G[y][x+dx]); dx--)
    				N[y][x+dx] = n;
    			if (sym)
    				p1 += n;
    			n = sym = 0;
    		}
    
    	/*
    	 * Pass 2: solve part 2 by finding all '*', then counting and
    	 * multiplying adjecent numbers.
    	 *
    	 * Horizontal adjecency is trivial but vertical/diagonal has
    	 * two situations: if there's a digit directly North of the '+',
    	 * it must be a single number: NW and NE would connect to it.
    	 * If N isn't a digit, digits in NW and NE belong to separate
    	 * numbers.
    	 */
    	for (y=1; y<=h; y++)
    	for (x=1; G[y][x]; x++) {
    		if (G[y][x] != '*')
    			continue;
    
    		n = 0; r = 1;
    
    		if (N[y][x-1]) { n++; r *= N[y][x-1]; }
    		if (N[y][x+1]) { n++; r *= N[y][x+1]; }
    
    		if (N[y-1][x]) { n++; r *= N[y-1][x]; } else {
    			if (N[y-1][x-1]) { n++; r *= N[y-1][x-1]; }
    			if (N[y-1][x+1]) { n++; r *= N[y-1][x+1]; }
    		}
    
    		if (N[y+1][x]) { n++; r *= N[y+1][x]; } else {
    			if (N[y+1][x-1]) { n++; r *= N[y+1][x-1]; }
    			if (N[y+1][x+1]) { n++; r *= N[y+1][x+1]; }
    		}
    
    		if (n == 2)
    			p2 += r;
    	}
    
    	printf("%d %d\n", p1, p2);
    	return 0;
    }