# Matrix creation in python

In a block of code I found the following thing

``````M = [3,4,5]

from math import *

class matrix:

# implements basic operations of a matrix class

def __init__(self, value):
self.value = value
self.dimx = len(value)
self.dimy = len(value[0])
if value == [[]]:
self.dimx = 0

def zero(self, dimx, dimy):
# check if valid dimensions
if dimx < 1 or dimy < 1:
raise ValueError, "Invalid size of matrix"
else:
self.dimx = dimx
self.dimy = dimy
self.value = [[0 for row in range(dimy)] for col in range(dimx)]

def identity(self, dim):
# check if valid dimension
if dim < 1:
raise ValueError, "Invalid size of matrix"
else:
self.dimx = dim
self.dimy = dim
self.value = [[0 for row in range(dim)] for col in range(dim)]
for i in range(dim):
self.value[i][i] = 1

def show(self):
for i in range(self.dimx):
print self.value[i]
print ' '

# check if correct dimensions
if self.dimx != other.dimx or self.dimy != other.dimy:
raise ValueError, "Matrices must be of equal dimensions to add"
else:
res = matrix([[]])
res.zero(self.dimx, self.dimy)
for i in range(self.dimx):
for j in range(self.dimy):
res.value[i][j] = self.value[i][j] + other.value[i][j]
return res

def __sub__(self, other):
# check if correct dimensions
if self.dimx != other.dimx or self.dimy != other.dimy:
raise ValueError, "Matrices must be of equal dimensions to subtract"
else:
# subtract if correct dimensions
res = matrix([[]])
res.zero(self.dimx, self.dimy)
for i in range(self.dimx):
for j in range(self.dimy):
res.value[i][j] = self.value[i][j] - other.value[i][j]
return res

def __mul__(self, other):
# check if correct dimensions
if self.dimy != other.dimx:
raise ValueError, "Matrices must be m*n and n*p to multiply"
else:
# subtract if correct dimensions
res = matrix([[]])
res.zero(self.dimx, other.dimy)
for i in range(self.dimx):
for j in range(other.dimy):
for k in range(self.dimy):
res.value[i][j] += self.value[i][k] * other.value[k][j]
return res

def transpose(self):
# compute transpose
res = matrix([[]])
res.zero(self.dimy, self.dimx)
for i in range(self.dimx):
for j in range(self.dimy):
res.value[j][i] = self.value[i][j]
return res

# Thanks to Ernesto P. Adorio for use of Cholesky and CholeskyInverse functions

def Cholesky(self, ztol=1.0e-5):
# Computes the upper triangular Cholesky factorization of
# a positive definite matrix.
res = matrix([[]])
res.zero(self.dimx, self.dimx)

for i in range(self.dimx):
S = sum([(res.value[k][i])**2 for k in range(i)])
d = self.value[i][i] - S
if abs(d) < ztol:
res.value[i][i] = 0.0
else:
if d < 0.0:
raise ValueError, "Matrix not positive-definite"
res.value[i][i] = sqrt(d)
for j in range(i+1, self.dimx):
S = sum([res.value[k][i] * res.value[k][j] for k in range(self.dimx)])
if abs(S) < ztol:
S = 0.0
res.value[i][j] = (self.value[i][j] - S)/res.value[i][i]
return res

def CholeskyInverse(self):
# Computes inverse of matrix given its Cholesky upper Triangular
# decomposition of matrix.
res = matrix([[]])
res.zero(self.dimx, self.dimx)

# Backward step for inverse.
for j in reversed(range(self.dimx)):
tjj = self.value[j][j]
S = sum([self.value[j][k]*res.value[j][k] for k in range(j+1, self.dimx)])
res.value[j][j] = 1.0/tjj**2 - S/tjj
for i in reversed(range(j)):
res.value[j][i] = res.value[i][j] = -sum([self.value[i][k]*res.value[k][j] for k in range(i+1, self.dimx)])/self.value[i][i]
return res

def inverse(self):
aux = self.Cholesky()
res = aux.CholeskyInverse()
return res

def __repr__(self):
return repr(self.value)

for n in range(len(M)):
Z = matrix([[M[n]]])
Z.show()
``````

Now If I run the code I got the following output:

``````[3]
[4]
[5]
``````

Now I don't understand what the output means and how to interpret this one. Specifically the following line of code in above I could not understand

``````Z = matrix([[M[n]]])
``````

Can anyone please explain me the output of the code and the single line above?

-
You could be better of using numpy matrix class. docs.scipy.org/doc/numpy/reference/generated/numpy.matrix.html –  DhruvPathak Aug 31 '12 at 8:20
...is this from Udacity CS373? –  Andy Hayden Aug 31 '12 at 8:45

The last for loop is the one deciding the output:

``````for n in range(len(M)):
Z = matrix([[M[n]]])
Z.show()
``````

Since `M=[3,4,5]`, this calls the second two lines three times:

``````Z = matrix([[3]])
Z.show()
Z = matrix([[4]])
Z.show()
Z = matrix([[5]])
Z.show()
``````

Each time we set `Z` as a 1x1 matrix e.g. `[[3]]`, and apply the `show` matrix method, which essentially prints `Z` in nice way.

-

The code creates three 1x1 matrices, i.e. three matrices where each matrix contains a single element, and prints them. That's the `[3]`, `[4]`, `[5]` you're seeing: three 1x1 matrices.

For the `[[M[n]]]`: The matrix constructor expects a value for the matrix, which is a two-dimensional array. This explains the `[[ .. ]]`. You could construct a 2x2 unit matrix by calling

``````data = [ [1,0], [0,1] ]
matrix(data)
``````

(That is a list that contains two other lists, each of which have two elements.)

In this case, the matrices are initialised with a single element each, which happens to be `M[n]`.

The code could be simplified to:

``````for n in M:
Z = matrix([[n]])
Z.show()
``````

which makes it easier to read

-