# A function that takes two matrices as input, and returns a matrix with A * B. In Python

I am trying to figure out how to create a dot product matrix. Here is the code I have made so far:

``````C = [[4,1,9], [6,2,8], [7,3,5]]
D = [[2,9], [5,2], [1,0]]

def prettyPrint(A):
for i in range(len(A)):
line = "{0: >7}".format("|"+str(A[i][0]))
for j in range(1, len(A[i])):
line = line + "{0: >7}".format(str(A[i][j]))
line = line + "|"
print(line)
Z = []
for i in range(len(A)):
row = []
for j in range(len(A[0])):
row.append(A[i][j]+B[i][j])
Z.append(row)
return Z
#for subtraction of vectors
def matrixSUB(A,B):
Z = []
for i in range(len(A)):
row = []
for j in range(len(A[0])):
row.append(A[i][j]-B[i][j])
Z.append(row)
return Z
#for multiplication of vectors
def row(A,i):
Z = []
Z.extend(A[i])
return Z

def col(B,j):
Z = []
for row in B:
Z.append(row[j])
return Z

def dotProduct(x,y):
prod = 0
prod = sum(p*q for p,q in zip(x,y))
return prod

def matrixMUL(A,B):
Z = []
#Need to do.
return Z

print("\nC * D:")
prettyPrint(matrixMUL(C,D))
``````

It's the `matrixMUL(A,B)` part that I am having trouble with. The program is supposed to go through this kind of calculation: Example:

``````Z = C * D =
row(C,0) • col(D,0)   row(C,0) • col(D,1)
row(C,1) • col(D,0)   row(C,1) • col(D,1)
row(C,2) • col(D,0)   row(C,2) • col(D,1)
Z =
(4*2 + 1*5 + 9*1)   (4*9 + 1*2 + 9*0)
(6*2 + 2*5 + 8*1)   (6*9 + 2*2 + 8*0)
(7*2 + 3*5 + 5*1)   (7*9 + 3*2 + 5*0)
Z =
22    38
30    58
34    69
``````

and then have just this print statement:

``````C * D:
|22     38|
|30     58|
|34     69|
``````

I NEED to use the other tree (or three? don't know if there is a typo or not) functions. I've been trying this for the last three days and have looked up about everything I can think of. This is some of the code I have tried which have failed (I just comment out the stuff that went wrong):

``````def matrixMUL(A,B):
Z = []
Z.append(int(dotProduct(row(A,B),col(A,B))))
#if len(col(B,j)) != len(row(A,i)):
#print("Cannot multiply the two matrices. Incorrect dimensions.")
#else:
#for n in range(row(A,i)):
#for m in range(col(B,j)):
#Z.append(dotProduct(x,y))
return Z
#mult = sum(p*q for p,q in zip(x,y))
#Z.append(mult)
#Z = []
#for i in range(len(A)):
#row = []
#for j in range(len(A[0])):
#row.append(A[i][j]+B[i][j])
#Z.append(row)
#return Z
``````

I don't know what else I can try. Can someone help?

-
Is there a reason that you don't want to use numpy? If not, you should take a look at it. It provides a very broad number of array manipulation routines including dot and cross product. –  Vorticity Mar 28 '13 at 18:40
we cant use numpy. –  Sofia June Mar 28 '13 at 19:34

You can do it this way:

``````def matrixMUL(A,B):
Z = [[0] * len(B[0]) for zz in range(len(A))]
for i in range(0,len(A)):
a = row(A,i)
for j in range(0,len(B[0])):
b = col(B,j)
Z[i][j] = sum(p*q for p,q in zip(a,b))
return Z
``````

A difficulty that I've encountered when writing code like this is initialising the matrix correctly in the first place.

If we use code like `Z = [[0] * len(B[0])] * len(A)`, then we end up creating a list `Z` that contains `len(A)` references to the same list of length `len(B[0])` zeros. Thus, code like `z[0][0] = 1` will appear to "magically" change `Z[1][0]` and `Z[2][0]` to equal `1` at the same time, because all of these refer to the same element in the same list.

By initialising the matrix `Z` with a list comprehension as shown above, we can be sure we have a set of unique lists referred to in `Z`.

Another approach that avoids the need to initialise all of `Z` (and thus avoids the list reference problem entirely) is:

``````def matrixMUL2(A,B):
Z = []
for i in range(0,len(A)):
a = row(A,i)
r = []
for j in range(0,len(B[0])):
b = col(B,j)
r.append(sum(p*q for p,q in zip(a,b)))
Z.append(r)
return Z
``````

Neither function does as much error checking as it should (e.g. checking that the matrices have corresponding dimension sizes, as is required for multiplication), so they are not up to a good production-code standard as yet. Also, as has been suggested in comments, if `numpy` was available, I'd highly recommend using `numpy` instead of writing one's own code for this.

-
OMG!!!!!! THANK YOU THANK YOU THANK YOU!!!! I couldn't for the life of me figure it out. Instead of using `r.append(sum(p*q for p,q in zip(a,b)))` I used `r.append(dotProduct(a,b))` so it's the same thing really. Omg you are awesome sir. I actually love you. <3 –  Sofia June Mar 29 '13 at 4:00