# How to check for equality element-wise for two vectors?

I have two vectors that I need to check element wise for equality and return the total number of elements that are equal. So comparing a = {1,0,1} and b = {1,0,0} would return 2.

The example below is an effort I've made of a recursive function, but is returning errors.

Elementcompare[list1_, list2_] :=   If[First[list1] == First[list2], 1, 0]  + Elementcompare[Rest[list1], Rest[list2]];


Thanks

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I assume length of vectors is the same in general. There is a function for this - HammingDistance you can use it to define:

elcom[a_List, b_List] := Length[a] - HammingDistance[a, b]


Test it out

elcom[a, b]


2

Also check out EditDistance .

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Perfect, thank you for the help. –  Mike Dec 14 '12 at 16:40

An easy and fast method is to use vector-level numeric operations.

a = {0, 1, 0, 1, 2};

b = {2, 1, 3, 1, 2};

a - b

{-2, 0, -3, 0, 0}

Unitize[a - b]

{1, 0, 1, 0, 0}

Tr @ Unitize[a - b]

2


This is equivalent to HammingDistance in this use:

HammingDistance[a, b]

2


I use Tr to sum because it is very fast on packed arrays. Speed comparison with HammingDistance on version 7 with two long lists:

a = RandomInteger[3, 500000];
b = RandomInteger[3, 500000];

Do[HammingDistance[a, b], {50}] // Timing // First

Do[Tr @ Unitize[a - b], {50}]   // Timing // First

0.968

0.171


Performance is more similar when a and b are not packed arrays but the numeric method still wins. You can subtract the returned value from Length[a] to get your target metric just as Vitaliy showed.

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If your vectors are bit-vectors (0s and 1s), you can squeeze more speed out of this computation by using bit operators:

a = RandomInteger[1, 500000];

b = RandomInteger[1, 500000];


First, check for consistency:

HammingDistance[a, b]


249965

Tr@Unitize[a - b]


249965

Total@BitXor[a, b]


249965

Check for speed:

Do[HammingDistance[a, b], {50}] // Timing // First


1.98993

Do[Tr@Unitize[a - b], {50}] // Timing // First


0.437551

Do[Total@BitXor[a, b], {50}] // Timing // First


0.139816

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