# Multiplying polynomials in python

I did the adding and the subtracting but I am having a really hard time multiplying to polynomials in python.

For example, if I have:

``````2X^2 + 5X + 1 [1,5,2]
``````

and...

``````3X^3 + 4X^2 + X + 6 [6,1,4,3]
``````

We get:

``````6X^5 + 23X^4 + 25X^3 + 21X^2 + 31X + 6 [6,31,21,25,23,6]
``````

I am desperate. I have been working at it for days. Any help would be appreciated

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Might be a dumb question since I'm not a huge Python user, but have you looked at this library: numpy.scipy.org –  eulerfx Mar 24 '11 at 0:02
Are you having trouble with python, or with the algorithm? –  Joel Lee Mar 24 '11 at 0:08
Numpy's got the routines, but this almost certainly a homework problem, so the OP will need his own code to work. –  user57368 Mar 24 '11 at 0:08
@Joel.I am having trouble with the algorithm –  steff Mar 24 '11 at 0:14

``````s1 = [1,5,2]
s2 = [6,1,4,3]
res = [0]*(len(s1)+len(s2)-1)
for o1,i1 in enumerate(s1):
for o2,i2 in enumerate(s2):
res[o1+o2] += i1*i2
``````

Edit: In honor of @katrielalex:

``````import collections
import itertools

class Polynomial(object):
def __init__(self, *args):
"""
Create a polynomial in one of three ways:

p = Polynomial(poly)           # copy constructor
p = Polynomial([1,2,3 ...])    # from sequence
p = Polynomial(1, 2, 3 ...)    # from scalars
"""
super(Polynomial,self).__init__()
if len(args)==1:
val = args[0]
if isinstance(val, Polynomial):                # copy constructor
self.coeffs = val.coeffs[:]
elif isinstance(val, collections.Iterable):    # from sequence
self.coeffs = list(val)
else:                                          # from single scalar
self.coeffs = [val+0]
else:                                              # multiple scalars
self.coeffs = [i+0 for i in args]
self.trim()

"Return self+val"
if isinstance(val, Polynomial):                    # add Polynomial
res = [a+b for a,b in itertools.izip_longest(self.coeffs, val.coeffs, fillvalue=0)]
if self.coeffs:
res = self.coeffs[:]
res[0] += val
else:
res = val
return self.__class__(res)

def __call__(self, val):
"Evaluate at X==val"
res = 0
pwr = 1
for co in self.coeffs:
res += co*pwr
pwr *= val
return res

def __eq__(self, val):
"Test self==val"
if isinstance(val, Polynomial):
return self.coeffs == val.coeffs
else:
return len(self.coeffs)==1 and self.coeffs[0]==val

def __mul__(self, val):
"Return self*val"
if isinstance(val, Polynomial):
_s = self.coeffs
_v = val.coeffs
res = [0]*(len(_s)+len(_v)-1)
for selfpow,selfco in enumerate(_s):
for valpow,valco in enumerate(_v):
res[selfpow+valpow] += selfco*valco
else:
res = [co*val for co in self.coeffs]
return self.__class__(res)

def __neg__(self):
"Return -self"
return self.__class__([-co for co in self.coeffs])

def __pow__(self, y, z=None):
raise NotImplemented()

"Return val+self"
return self+val

def __repr__(self):
return "{0}({1})".format(self.__class__.__name__, self.coeffs)

def __rmul__(self, val):
"Return val*self"
return self*val

def __rsub__(self, val):
"Return val-self"
return -self + val

def __str__(self):
"Return string formatted as aX^3 + bX^2 + c^X + d"
res = []
for po,co in enumerate(self.coeffs):
if co:
if po==0:
po = ''
elif po==1:
po = 'X'
else:
po = 'X^'+str(po)
res.append(str(co)+po)
if res:
res.reverse()
return ' + '.join(res)
else:
return "0"

def __sub__(self, val):
"Return self-val"

def trim(self):
"Remove trailing 0-coefficients"
_co = self.coeffs
if _co:
offs = len(_co)-1
if _co[offs]==0:
offs -= 1
while offs >= 0 and _co[offs]==0:
offs -= 1
del _co[offs+1:]
``````
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I think this would look a lot neater with non-numerical variable names or even in pseudocode; just my two cents. –  katrielalex Mar 24 '11 at 2:05
@katrielalex: hope that's an improvement ;-) –  Hugh Bothwell Mar 24 '11 at 2:40
Why do you have that "super(Polynomial,self).__init__()"? I've only seen that in the context of inheriting classes. –  riri Mar 24 '11 at 3:04
@riri: yes; Polynomial inherits from object. It takes care of odd problems such as diamond inheritance (D inherits from B and C which each inherit from A; who initializes A?). It's basically just insurance that the class behaves properly for people creating new classes based on it. –  Hugh Bothwell Mar 24 '11 at 3:19
+1 for the insane effort and how thoroughly you solved the problem, despite the fact that you might be doing someone's homework. –  SimonT Jun 1 '13 at 0:33
show 1 more comment
``````In [1]: from numpy import convolve

In [2]: convolve([1,5,2],[6,1,4,3])
Out[2]: array([ 6, 31, 21, 25, 23,  6])
``````
-
``````q = [6,1,4,3]
p = [1,5,2]
qa = zip(q, [3,2,1,0])
pa = zip(p, [2,1,0])
res = {}
for a in qa:
for b in pa:
if a[1] + b[1] in res:
res[a[1] + b[1]] += a[0]*b[0]
else:
res[a[1] + b[1]] = a[0]*b[0]
print res
``````

Of course, you would need to add a little bit more to make it work for general polynomials. You could also make it faster with some of the things they use for FFTs (I think).

-
``````s1 = [1,5,2]
s2 = [6,1,4,3]
mlist = [ [0]*o2+[i1*i2 for i1 in s1]+[0]*(len(s1)-o2) for o2,i2 in enumerate(s2)]
length = len(s1)+len(s2)-1
res = [ sum(row[i] for row in mlist) for i in range(length)]
``````

==

or in one huge comprehension:

``````res = [ sum( row[i]
for row
in [ [0]*o2
+[i1*i2 for i1 in s1]
+[0]*(len(s1)-o2)
for o2,i2
in enumerate(s2)
]
)
for i
in range( len(s1)+len(s2)-1 )
]
``````
-
I am trying to do this my way because I can not use the enumerate built in function and it prints the right length for the list but not the right numbers. :( –  steff Mar 24 '11 at 3:13
on "Python 3.3.0 (v3.3.0:bd8afb90ebf2, Sep 29 2012, 10:55:48) [MSC v.1600 32 bit (Intel)] on win32", with s1=[1,5] and s2=[6,1,4,3] I get an IndexError: list index out of range –  miracle173 Nov 4 '13 at 21:05

The following comprehension implements polynomial multiplication using the usual definition by adding dummy terms with 0 coefficients to the factor polynomials `p`and `q`:

``````(p[0]+p[1]*X+p[2]*X^2+...)*(q[0]+q[1]*X+q[2]*X^2+...)=
(p[0]*q[0])+(p[0]*q[1]+p[1]*q[0])X+(p[0]*q[2]+p[1]*q[1]+p[2]*q[0])X^2+...
``````

So `(p+[0]*(len(q)-1))` extends the list `p` by `len(q)-1` zeroes to a list of lenght `len(p)+len(q)-1`

``````[sum([ (p+[0]*(len(q)-1))[i]*(q+[0]*(len(p)-1))[k-i]
for i in range(1+k)
]
) for k in range(len(p)+len(q)-1)]
``````

The following comprehension avoids adding dummy 0-coefficient terms to the polynomials `p` and `q` by choosing a proper start and end for the range of the indices

``````[sum([ p[i]*q[k-i]
for i in range(
max([0,k-len(q)+1]),
1+min([k,len(p)-1])
)
]
) for k in range(len(p)+len(q)-1)]
``````

For

``````p=[6,1,4,3]
q=[1,5,2]
``````

the result is

``````[6, 31, 21, 25, 23, 6]
``````
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