For your application I suspect you don't need exact degrees and would prefer a more approximate compass angle, eg 1 of 16 directions? If so then this code avoids atan issues and indeed avoids floating point altogether. It was written for a video game so uses 8 bit and 16 bit integers:
/*
349.75d 11.25d, tan=0.2034523
\ /
\ Sector /
\ 0 / 22.5d tan = ?2  1
15  1 33.75
 / 45d, tan = 1
14  2 _56.25
 / 67.5d, tan = 1 + ?2
13  3
 __ 78.75

12+4 90d tan = infty
 __ 101.25

11  5

10  6

9  7
8
*/
// use signs to map sectors:
static const int8_t map[4][5] = { /* +n means n >= 0, n means n < 0 */
/* 0: +x +y */ {0, 1, 2, 3, 4},
/* 1: +x y */ {8, 7, 6, 5, 4},
/* 2: x +y */ {0, 15, 14, 13, 12},
/* 3: x y */ {8, 9, 10, 11, 12}
};
int8_t sector(int8_t x, int8_t y) { // x,y signed in range 128:127, result 0:15 from north, clockwise.
int16_t tangent; // 16 bits
int8_t quadrant = 0;
if (x > 0) x = x; else quadrant = 2; // make both negative avoids issue with negating 128
if (y > 0) y = y; else quadrant = 1;
if (y != 0) {
// The primary cost of this algorithm is five 16bit multiplies.
tangent = (int16_t)x*32; // worst case y = 1, tangent = 255*32 so fits in 2 bytes.
/*
determine base sector using abs(x)/abs(y).
in segment:
0 if 0 <= x/y < tan 11.25  centered around 0 N
1 if tan 11.25 <= x/y < tan 33.75  22.5 NxNE
2 if tan 33.75 <= x/y < tan 56.25  45 NE
3 if tan 56.25 <= x/y < tan 78.75  67.5 ExNE
4 if tan 78.75 <= x/y < tan 90  90 E
*/
if (tangent > y*6 ) return map[quadrant][0]; // tan(11.25)*32
if (tangent > y*21 ) return map[quadrant][1]; // tan(33.75)*32
if (tangent > y*47 ) return map[quadrant][2]; // tan(56.25)*32
if (tangent > y*160) return map[quadrant][3]; // tan(78.75)*32
// last case is the potentially infinite tan(90) but we don't need to check that limit.
}
return map[quadrant][4];
}