Sorry for not using Matlab, but I only worked with Python a little bit. I think this code may help you (sorry for bad codestyle -- I'm mathematician, not programmer)
import numpy as np
# input data
ins = [[1, 1], [2, 3], [3, 2]] # <- points
out = [[0, 2], [1, 2], [-2, -1]] # <- mapped to
l = len(ins)
B = np.vstack([np.transpose(ins), np.ones(l)])
D = 1.0 / np.linalg.det(B)
entry = lambda r,d: np.linalg.det(np.delete(np.vstack([r, B]), (d+1), axis=0))
M = [[(-1)**i * D * entry(R, i) for i in range(l)] for R in np.transpose(out)]
A, t = np.hsplit(np.array(M), [l-1])
t = np.transpose(t)
print("Affine transformation matrix:\n", A)
print("Affine transformation translation vector:\n", t)
for p, P in zip(np.array(ins), np.array(out)):
image_p = np.dot(A, p) + t
result = "[OK]" if np.allclose(image_p, P) else "[ERROR]"
print(p, " mapped to: ", image_p, " ; expected: ", P, result)
This code demonstrates how to recover affine transformation as matrix and vector and tests that initial points are mapped to where they should. You can test this code with Google colab, so you don't have to install anything. Probably, you can translate it to Matlab.
Regarding theory behind this code: it is based on equation presented in "Beginner's guide to mapping simplexes affinely", matrix recovery is described in section "Recovery of canonical notation". The same authors published "Workbook on mapping simplexes affinely" that contains many practical examples of this kind.