def solve_tsp_by_mip(tsp_matrix):
start = time()
matrix_of_distances = get_matrix_of_distances(tsp_matrix)
length = len(tsp_matrix)
model = Model(solver_name='gurobi')
model.verbose = 1
x = [[model.add_var(var_type=BINARY) for j in range(length)]
for i in range(length)]
y = [model.add_var() for i in range(length)]
model.objective = xsum(matrix_of_distances[i][j] * x[i][j]
for j in range(length) for i in range(length))
for i in range(length):
model += xsum(x[j][i] for j in range(length) if j != i) == 1
model += xsum(x[i][j] for j in range(length) if j != i) == 1
for i in range(1, length):
for j in [x for x in range(1, length) if x != i]:
model += y[i] - (length + 1) * x[i][j] >= y[j] - length
model.optimize(max_seconds=300)
arcs = [(i, j) for i in range(length) for j in range(length)
if x[i][j].x >= 0.99]
best_distance = calculate_total_dist_by_arcs(matrix_of_distances, arcs)
time_diff = time() - start
return arcs, time_diff, best_distance
def test_queens(solver: str):
"""MIP model n-queens"""
n = 50
announce_test("n-Queens", solver)
queens = Model('queens', MAXIMIZE, solver_name=solver)
queens.verbose = 0
x = [[
queens.add_var('x({},{})'.format(i, j), var_type=BINARY)
for j in range(n)
] for i in range(n)]
# one per row
for i in range(n):
queens += xsum(x[i][j] for j in range(n)) == 1, 'row({})'.format(i)
# one per column
for j in range(n):
queens += xsum(x[i][j] for i in range(n)) == 1, 'col({})'.format(j)
# diagonal \
for p, k in enumerate(range(2 - n, n - 2 + 1)):
queens += xsum(x[i][j] for i in range(n) for j in range(n)
if i - j == k) <= 1, 'diag1({})'.format(p)
# diagonal /
for p, k in enumerate(range(3, n + n)):
queens += xsum(x[i][j] for i in range(n) for j in range(n)
if i + j == k) <= 1, 'diag2({})'.format(p)
queens.optimize()
check_result("model status", queens.status == OptimizationStatus.OPTIMAL)
# querying problem variables and checking opt results
total_queens = 0
for v in queens.vars:
# basic integrality test
assert v.x <= 0.0001 or v.x >= 0.9999
total_queens += v.x
# solution feasibility
rows_with_queens = 0
for i in range(n):
if abs(sum(x[i][j].x for j in range(n)) - 1) <= 0.001:
rows_with_queens += 1
check_result("feasible solution",
abs(total_queens - n) <= 0.001 and rows_with_queens == n)
print('')
def solve_tsp_by_mip_with_sub_cycles_2(tsp_matrix):
start = time()
matrix_of_distances = get_matrix_of_distances(tsp_matrix)
total_length = len(tsp_matrix)
best_distance = sys.float_info.max
found_cycles = []
arcs = [(i, i + 1) for i in range(total_length - 1)]
iteration = 0
model = Model(solver_name='gurobi')
model.verbose = 0
x = [[model.add_var(var_type=BINARY) for j in range(total_length)]
for i in range(total_length)]
y = [model.add_var() for i in range(total_length)]
model.objective = xsum(matrix_of_distances[i][j] * x[i][j]
for j in range(total_length)
for i in range(total_length))
for i in range(total_length):
model += (xsum(x[i][j] for j in range(0, i)) +
xsum(x[j][i] for j in range(i + 1, total_length))) == 2
while len(found_cycles) != 1:
model.optimize(max_seconds=300)
arcs = [(i, j) for i in range(total_length)
for j in range(total_length) if x[i][j].x >= 0.99]
best_distance = calculate_total_dist_by_arcs(matrix_of_distances, arcs)
found_cycles = get_cycle(arcs)
for cycle in found_cycles:
points = {}
for arc in cycle:
points = {*points, arc[0]}
points = {*points, arc[1]}
cycle_len = len(cycle)
model += xsum(x[arc[0]][arc[1]]
for arc in permutations(points, 2)) <= cycle_len - 1
# plot_connected_tsp_points_from_arcs(tsp_matrix, arcs, '../images/mip_xql662/{}'.format(iteration))
print(iteration)
iteration += 1
time_diff = time() - start
return arcs, time_diff, best_distance
def test_tsp_mipstart(solver: str):
"""tsp related tests"""
announce_test("TSP - MIPStart", solver)
N = ['a', 'b', 'c', 'd', 'e', 'f', 'g']
n = len(N)
i0 = N[0]
A = {
('a', 'd'): 56,
('d', 'a'): 67,
('a', 'b'): 49,
('b', 'a'): 50,
('d', 'b'): 39,
('b', 'd'): 37,
('c', 'f'): 35,
('f', 'c'): 35,
('g', 'b'): 35,
('b', 'g'): 25,
('a', 'c'): 80,
('c', 'a'): 99,
('e', 'f'): 20,
('f', 'e'): 20,
('g', 'e'): 38,
('e', 'g'): 49,
('g', 'f'): 37,
('f', 'g'): 32,
('b', 'e'): 21,
('e', 'b'): 30,
('a', 'g'): 47,
('g', 'a'): 68,
('d', 'c'): 37,
('c', 'd'): 52,
('d', 'e'): 15,
('e', 'd'): 20
}
# input and output arcs per node
Aout = {n: [a for a in A if a[0] == n] for n in N}
Ain = {n: [a for a in A if a[1] == n] for n in N}
m = Model(solver_name=solver)
m.verbose = 0
x = {
a: m.add_var(name='x({},{})'.format(a[0], a[1]), var_type=BINARY)
for a in A
}
m.objective = xsum(c * x[a] for a, c in A.items())
for i in N:
m += xsum(x[a] for a in Aout[i]) == 1, 'out({})'.format(i)
m += xsum(x[a] for a in Ain[i]) == 1, 'in({})'.format(i)
# continuous variable to prevent subtours: each
# city will have a different "identifier" in the planned route
y = {i: m.add_var(name='y({})'.format(i), lb=0.0) for i in N}
# subtour elimination
for (i, j) in A:
if i0 not in [i, j]:
m.add_constr(y[i] - (n + 1) * x[(i, j)] >= y[j] - n)
route = ['a', 'g', 'f', 'c', 'd', 'e', 'b', 'a']
m.start = [(x[route[i - 1], route[i]], 1.0) for i in range(1, len(route))]
m.optimize()
check_result("mip model status", m.status == OptimizationStatus.OPTIMAL)
check_result("mip model objective",
(abs(m.objective_value - 262)) <= 0.0001)
print('')
