I show here how a "difficult" instance of this problem can be solved. I think this method can be generalized. I have put another simpler instance in the comments of the original post.

Consider the two lines:

```
10000019 * X - 10000015 * Y + 909093 >= 0 (L1)
-10000022 * X + 10000018 * Y + 1428574 >= 0 (L2)
A = 10000019, B = -10000015, C = -909093
```

The intersection point is H:

```
Hx = -5844176948071/3, Hy = -5844179285738/3
```

For a point M(X,Y), the squared distance HM^2 is:

```
HM^2 = (9*X^2+35065061688426*X
+68308835724213587680825685
+9*Y^2+35065075714428*Y)/9
```

g = gcd(A,B) = 1: the equation of L1 `A*X+B*Y+909093`

can take any integer value.

Bezout coefficients, U=2500004 and V=2500005 verify:

```
A * U + B * V = 1
```

We now rewrite the problem in the "dual" basis (K,T) defined by:

```
X = T*U - K*B
Y = T*V + K*A
```

After substitution, we get:

```
T+909093 >= 0
2*T+12*K+1428574 >= 0
minimize 112500405000369*T^2
+900003150002790*T*K
+1800006120005274*K^2
+175325659092760325844*T
+701302566240903900522*K
+Constant
```

After further translating (first on T, then on K to minimize the
constant in the second equation), T=T1-909093, K=K1+32468:

```
T1 >= 0
2*T1+4+12*K1 >= 0
minimize 112500405000369*T1^2
+300001050000930*T1
+900003150002790*T1*K1
+1200004080003516*K1
+1800006120005274*K1^2
+Constant
```

The algorithm I proposed is to loop on T1. Actually, we don't need to
loop here, since the best result is given by T1=K1=0, corresponding to:

```
X = -1948055649352, Y = -1948056428573
```

My initial post below.

Here is another idea of algorithm. It may work, but I did not implement it...

With appropriate change of signs to match the position of (x,y), the problem can be written:

```
A*X+B*Y>=C (line D)
a*X+b*Y>=c (line d)
minimize the distance between M(X,Y) and H, the intersection point
A*b != a*B (intersection is defined)
A,B,C,a,b,c,X,Y all integers
```

The set of all values reached by (A*X+B*Y) is the set of all multiples of g=gcd(A,B), and there exist integers (u,v) such that A*u+B*v=g (Bezout theorem). From a point with integer coordinates (X0,Y0), all points with integer coordinates and the same value of A*X+B*Y are (X0-K*B/g,Y0+K*A/g), for all integers K.

To solve the problem, we can loop on lines parallel to D at increasing distance from H, and containing points with integer coordinates.

Compute g,u,v, and H (the coordinates of H are probably not needed, we only need the coefficients of the quadratic form corresponding to the distance).

T0 = ceil(C/g)

Loop from T = T0

a. Find K the smallest (or largest, depending on the sign of a*B-b*A) integer verifying a*(T*u-K*B/g)+b*(T*v+K*A/g)>=c

b. Keep point (T*u-K*B/g,T*v+K*A/g) if closer to H

c. Exit the loop when (T-T0) corresponds to a distance from D larger than the best result so far, otherwise continue with T+=1