# Can you help me understand this C# function?

I would like to write the following C# function in ColdFusion, but I am unable to because I can't understand the code. I know the function checks the validity of an 11 digit CPF number (Brazilian equivalent of US SSN) using a mod operation. I have absolutely no experience with C#.

I don't understand where cpf[0], cpf[1], etc... come from, and what the number between the square brackets refers to.

//compute 1st verification digit.
var v1 = 10 * cpf[0] + 9 * cpf[1] + 8 * cpf[2] + 7 * cpf[3] + 6 *
cpf[4] + 5 * cpf[5] + 4 * cpf[6] + 3 * cpf[7] + 2 * cpf[8];
v1 = 11 - v1 % 11;
if (v1 >= 10)
v1 = 0;
//compute 2nd verification digit.
var v2 = 11 * cpf[0] + 10 * cpf[1] + 9 * cpf[2] + 8 * cpf[3] + 7 *
cpf[4] + 6 * cpf[5] + 5 * cpf[6] + 4 * cpf[7] + 3 * cpf[8];
v2 += 2 * v1;
v2 = 11 - v2 % 11;
if (v2 >= 10)
v2 = 0;
//True if verification digits are as expected.
return v1 == cpf[9] && v2 == cpf[10];

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That's a lot of math, but I don't see anything particular complex about it from a coding perspective. What part specifically is it you don't understand? –  delnan Apr 30 '11 at 18:01
So what exactly is the question? Are there specific operators which you don't understand? –  Lucero Apr 30 '11 at 18:01
@delnan, I'm not sure what's going with v1, and v2, and where they come from. I'm also unsure of what cpf[0], cpf[1], etc... refer to.... –  Mohamad Apr 30 '11 at 18:02
v1 abd v2 are declared in the code you posted, what do you mean where do they come from? –  Oded Apr 30 '11 at 18:03
@Lucero, I just updated my question. See my comment above, too. –  Mohamad Apr 30 '11 at 18:03

Given the following CPF 012.345.678-90

//compute 1st verification digit.
var v1 = 10 * cpf[0] + // 10 x 0 = 0
9 * cpf[1] +       // 9  x 1 = 9
8 * cpf[2] +       // 8  x 2 = 16
7 * cpf[3] +       // 7  x 3 = 21
6 * cpf[4] +       // 6  x 4 = 24
5 * cpf[5] +       // 5  x 5 = 25
4 * cpf[6] +       // 4  x 6 = 24
3 * cpf[7] +       // 3  x 7 = 21
2 * cpf[8]         // 2  x 8 = 16
; // result = 156

v1 = 11 - v1 % 11;     // 11 - 156 % 11 = 11 - 2 = 9
if (v1 >= 10)
v1 = 0;            // 9 >= 10 ? v1 = 9

//compute 2nd verification digit.
var v2 = 11 * cpf[0] + // 11 x 0 = 0
10 * cpf[1] +      // 10 x 1 = 10
9 * cpf[2] +       // 9  x 2 = 18
8 * cpf[3] +       // 8  x 3 = 24
7 * cpf[4] +       // 7  x 4 = 28
6 * cpf[5] +       // 6  x 5 = 30
5 * cpf[6] +       // 5  x 6 = 30
4 * cpf[7] +       // 4  x 7 = 28
3 * cpf[8]         // 3  x 8 = 24
;

v2 += 2 * v1;          // 192 + 2 * 9 = 192 + 18 = 210
v2 = 11 - v2 % 11;     // 11 - 210 % 11 = 11 - 1 = 10
if (v2 >= 10)
v2 = 0;            // 10 >= 10 ? v2 = 0

//True if verification digits are as expected.
// v1 == 9 && v2 == 0
return v1 == cpf[9] && v2 == cpf[10];


It just breaks to pure math

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cpf[0] to cpf[10] are presumably the 11 digits of the CPF number. Presumably, this consists of 9 digits of "real" data, and 2 digits of checksum data. Presumably, these 2 digits are calculated as a linear combination of the other 9 digits, in modulo-11 arithmetic.

So this function is recomputing the checksum (v1 and v2), and then checking it matches the received checksum digits (cpf[9] and cpf[10]).

These checksum relationships are typically designed to prevent mistyping digits, or accidentally swapping neighbouring digits (similar schemes are used for ISBN, for example).

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so basicall, v1 = 10 * cpf[0] is like saying 10 * the first digit of the cpf number? –  Mohamad Apr 30 '11 at 18:06
@Mohamad: precisely. –  Oli Charlesworth Apr 30 '11 at 18:07

It's just the application of the number validation algorithm. cpf is 11-digit number you are checking.

There is nothing complex and C#-specific in the code.

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The article to which you linked appears to only show partial c# source code. Judging by the pseudocode in the prior section, cpf appears to be simply an array of 11 integers.

EDIT: There are a few code samples on Google in various languages.

These look more complete and might be easier for you to understand.

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It appears that cpf is an array of integers, with 11 items.

Each is accessed by index, so the first one is - cpf[0], the second cpf[1] etc...

v1 and v2 are declared in the function and are assigned the values of calculations.

The last line compares these calculated values to the two last array items in cpf, presumably check digits.

All in all this code looks like it performs a calculation on a the CPF number and checking if the CPF is valid.

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The equation is basically a very simple hash function which results in two "check digits."

This check digit "hash" can be used to verify the validity of the 9-digit number that the check digits are appended to much in the same way as MD5 and SHA1 hashes can be associated with files and used to verify that the proper data was transmitted or that no tampering had taken place before, during or after transmital.

The mathematics in this case are somewhat simple and arbitrary but will yield the same answer for the same input every time. You could tweak the equations many different ways and end up with valid check digits, as long as the same equations are used every time.

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Indeed you could. However, these particular equations will have been chosen to have nice properties (presumably preventing accidental swapping of neighbouring digits, for example). –  Oli Charlesworth Apr 30 '11 at 18:13
@Oli: Perhaps, but I noticed that the last step of each check digit calculation was a modulus result subtracted from a constant... This makes me think that the equations are fairly malleable. –  Paul Sasik Apr 30 '11 at 18:18