# Calculate Family Relationship from Genealogical Data

I would like to be able to calculate the family relationship between two individuals in a family tree, given the following data schema (simplified from my actual data schema, only showing columns that directly apply to this problem):

``````individual
----------
id
gender

child
----------
child_id
father_id
mother_id
``````

With this structure, how can one calculate the relationship between two individual id's (i.e. cousin, great grand uncle, etc.).

Also, as there are actually two relationships (i.e. A-B may be nephew whereas B-A is uncle), how can one generate the complement to the other (given uncle, and assuming we know gender, how might we generate nephew?). This is more of a trivial question, the former is what I'm really interested in.

Thanks all!

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This isn't directly an algorithmic solution or anything, but I thought you might be interested in how well Wolfram Alpha can parse genealogical relations from natural language: www48.wolframalpha.com/input/… –  Maciek Jun 30 '09 at 13:47
^very impressive ^^ –  Charles Ma Jun 30 '09 at 13:51
Aye, Wolfram Alpha is quite awesomely interesting :) –  defines Jun 30 '09 at 14:34
UPDATE I've completed my PHP implementation to calculate relationships based on the above data schema. My algorithm for LCA is far less than optimal but effective. I'll be posting my implementation as an answer soon and will post separate questions for a more optimized LCA algorithm and to determine more complex relationships (i.e. double cousins, incest, etc.). –  defines Jul 6 '09 at 14:22
@Maciek: Very interesting. www48.wolframalpha.com/input/… –  Chris Doggett Jul 7 '09 at 15:59

You'll first need to calculate the Lowest Common Ancestor of both A and B. Call this Lowest Common Ancestor C.

Then calculate the distance in steps from C to A (CA) and C to B (CB). These values should be indexed into another table that determines the relationship based on these two values. For example:

``````CA      CB      Relation
1       2       uncle
2       1       nephew
2       2       cousin
0       1       father
0       2       grandfather
``````

You might keep the basic relations in this table, and add "great-" for additional distances on certain relations like grandfather, ex.: (0, 3) = great-grandfather.

Hopefully this will point you in the right direction. Best of luck!

UPDATE: (I can't comment below your code, since I don't have the reputation yet.)

Your function aggrandize_relationships is a little off, I think. You can simplify it by prefixing "grand" if the offset is 1 or greater, then prefix "great-" (offset - 1) times. Your version might include the prefix "great grand great grand" for very distant relatives.(Not sure if I have the correct parameter in this explanation, but hopefully you get the gist of it. Also, no idea if your family tree is going that far back, but the point remains valid.)

UPDATE TOO: Sorry, the above is incorrect. I misread the default case, and thought it recursively called the function again. In my defense, I wasn't familiar with the "2nd great grandfather" notation, and always used "great great grandfather" myself. Code onward!!

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Awesome, thanks for the nudge, I'll see where it leads me! –  defines Jul 2 '09 at 16:36
This has lead me to what I believe to be the solution to the problem. It actually is slightly more complicated, with respect to canonical versus civil generations and the resulting 1st/2nd/etc cousins being 1/2/etc. times removed. Your link lead me to some further reading and I believe I have all the information needed now to build an algorithm and implement it. –  defines Jul 2 '09 at 16:51
You might need to not stop at the first lowest common ancestor found. For instance, do you want to distinguish between full and half siblings? Or between, say, normal first cousins and double first cousins (where two brothers marry two sisters and both pairs have children who would have all grandparents in common). Think about making your implementation bullet-proof against incest, too - which unfortunately occurs - like, if a father and grandfather are the same for a person, you do not want to overwrite that in a lookup table. –  Anon Jul 2 '09 at 19:59
@Anon Definitely a problem that had crossed my mind, but I think that will end up as a second question to revise/enhance my implementation once I've completed it. Thanks! –  defines Jul 6 '09 at 14:20
Thanks for the updates :) I enjoy the ordinal suffix myself, and while I do have a soft spot for redundancy, I hate counting/saying 'great great great...'. Currently the longest proven direct line in my family tree goes back 16 generations. I don't need 13 greats to count :-p –  defines Jul 7 '09 at 18:30

Below is my PHP implementation of my algorithm to calculate relationship. This is based upon the data schema I outlined in the original question. This only finds the "closest" i.e. shortest-path relationship between the two individuals, it does not resolve compound relationships such as half-siblings or double cousins.

Note that data access functions such as `get_father` and `get_gender` are written in the style of a database abstraction layer I always use. It should be fairly straightforward to understand what is going on, basically all dbms-specific functions such as `mysql_query` are replaced with generalized functions such as `db_query`; it is not very complicated at all, especially in the examples in this code, but feel free to post questions in comments if it isn't clear.

``````<?php
/* Calculate relationship "a is the ___ of b" */

define("GENDER_MALE", 1);
define("GENDER_FEMALE", 2);

function calculate_relationship(\$a_id, \$b_id)
{
if (\$a_id == \$b_id) {
return 'self';
}

\$lca = lowest_common_ancestor(\$a_id, \$b_id);
if (!\$lca) {
return false;
}
\$a_dist = \$lca[1];
\$b_dist = \$lca[2];

\$a_gen = get_gender(\$a_id);

// DIRECT DESCENDANT - PARENT
if (\$a_dist == 0) {
\$rel = \$a_gen == GENDER_MALE ? 'father' : 'mother';
return aggrandize_relationship(\$rel, \$b_dist);
}
// DIRECT DESCENDANT - CHILD
if (\$b_dist == 0) {
\$rel = \$a_gen == GENDER_MALE ? 'son' : 'daughter';
return aggrandize_relationship(\$rel, \$a_dist);
}

// EQUAL DISTANCE - SIBLINGS / PERFECT COUSINS
if (\$a_dist == \$b_dist) {
switch (\$a_dist) {
case 1:
return \$a_gen == GENDER_MALE ? 'brother' : 'sister';
break;
case 2:
return 'cousin';
break;
default:
return ordinal_suffix(\$a_dist - 2).' cousin';
}
}

// AUNT / UNCLE
if (\$a_dist == 1) {
\$rel = \$a_gen == GENDER_MALE ? 'uncle' : 'aunt';
return aggrandize_relationship(\$rel, \$b_dist, 1);
}
// NEPHEW / NIECE
if (\$b_dist == 1) {
\$rel = \$a_gen == GENDER_MALE ? 'nephew' : 'niece';
return aggrandize_relationship(\$rel, \$a_dist, 1);
}

// COUSINS, GENERATIONALLY REMOVED
\$cous_ord = min(\$a_dist, \$b_dist) - 1;
\$cous_gen = abs(\$a_dist - \$b_dist);
return ordinal_suffix(\$cous_ord).' cousin '.format_plural(\$cous_gen, 'time', 'times').' removed';
} //END function calculate_relationship

function aggrandize_relationship(\$rel, \$dist, \$offset = 0) {
\$dist -= \$offset;
switch (\$dist) {
case 1:
return \$rel;
break;
case 2:
return 'grand'.\$rel;
break;
case 3:
return 'great grand'.\$rel;
break;
default:
return ordinal_suffix(\$dist - 2).' great grand'.\$rel;
}
} //END function aggrandize_relationship

function lowest_common_ancestor(\$a_id, \$b_id)
{
\$common_ancestors = common_ancestors(\$a_id, \$b_id);

\$least_distance = -1;
\$ld_index = -1;

foreach (\$common_ancestors as \$i => \$c_anc) {
\$distance = \$c_anc[1] + \$c_anc[2];
if (\$least_distance < 0 || \$least_distance > \$distance) {
\$least_distance = \$distance;
\$ld_index = \$i;
}
}

return \$ld_index >= 0 ? \$common_ancestors[\$ld_index] : false;
} //END function lowest_common_ancestor

function common_ancestors(\$a_id, \$b_id) {
\$common_ancestors = array();

\$a_ancestors = get_ancestors(\$a_id);
\$b_ancestors = get_ancestors(\$b_id);

foreach (\$a_ancestors as \$a_anc) {
foreach (\$b_ancestors as \$b_anc) {
if (\$a_anc[0] == \$b_anc[0]) {
\$common_ancestors[] = array(\$a_anc[0], \$a_anc[1], \$b_anc[1]);
break 1;
}
}
}

return \$common_ancestors;
} //END function common_ancestors

function get_ancestors(\$id, \$dist = 0)
{
\$ancestors = array();

// SELF
\$ancestors[] = array(\$id, \$dist);

// PARENTS
\$parents = get_parents(\$id);
foreach (\$parents as \$par) {
if (\$par != 0) {
\$par_ancestors = get_ancestors(\$par, \$dist + 1);
foreach (\$par_ancestors as \$par_anc) {
\$ancestors[] = \$par_anc;
}
}
}

return \$ancestors;
} //END function get_ancestors

function get_parents(\$id)
{
return array(get_father(\$id), get_mother(\$id));
} //END function get_parents

function get_father(\$id)
{
\$res = db_result(db_query("SELECT father_id FROM child WHERE child_id = %s", \$id));
return \$res ? \$res : 0;
} //END function get_father

function get_mother(\$id)
{
\$res = db_result(db_query("SELECT mother_id FROM child WHERE child_id = %s", \$id));
return \$res ? \$res : 0;
} //END function get_mother

function get_gender(\$id)
{
return intval(db_result(db_query("SELECT gender FROM individual WHERE id = %s", \$id)));
}

function ordinal_suffix(\$number, \$super = false)
{
if (\$number % 100 > 10 && \$number %100 < 14) {
\$os = 'th';
} else if (\$number == 0) {
\$os = '';
} else {
\$last = substr(\$number, -1, 1);

switch(\$last) {
case "1":
\$os = 'st';
break;
case "2":
\$os = 'nd';
break;
case "3":
\$os = 'rd';
break;
default:
\$os = 'th';
}
}

\$os = \$super ? '<sup>'.\$os.'</sup>' : \$os;

return \$number.\$os;
} //END function ordinal_suffix

function format_plural(\$count, \$singular, \$plural)
{
return \$count.' '.(\$count == 1 || \$count == -1 ? \$singular : \$plural);
} //END function plural_format

?>
``````

As I had mentioned previously, the algorithm to determine LCA is far less than optimal. I plan to post a separate question to optimize that, and another to address the problem of calculating compound relationships such as double cousins.

Many thanks to everyone who helped prod me in the right direction! With your tips, this turned out to be much easier than I originally thought.

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I will leave this open without accepting an answer for at least 2 days to allow for further discussion, pointing out any silly mistakes I made, suggestions for improvement, etc. –  defines Jul 6 '09 at 15:05

This might help The Tree Relationship Calculator is an object that accepts an XML representation of a tree and will calculate the relationship of any two members within it. This article describes how relationships are calculated, and what terms like second cousin, or first cousin once removed, mean. This code includes an object for calculating relationships, written in JavaScript, as well as a web UI for rendering and interacting with the tree. The example project is setup as a classic ASP page.

http://www.codeproject.com/Articles/30315/Tree-Relationship-Calculator

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This might help you, it's a lot of theory and implementation of SQL queries to generate and query tree structures

http://www.artfulsoftware.com/mysqlbook/sampler/mysqled1ch20.html

In particular, look at the adjacency list model which uses a family tree as example.

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Thanks for the link, but I already have implemented most of what is demonstrated on that page. I need to calculate family relationships, which is considerably more complex than those examples. –  defines Jun 30 '09 at 15:23

As strange as it might sound PROLOG seems to be the thing you're looking for. Given following ad-hoc program (http://www.pastey.net/117134 better colouring)

``````female(alice).
female(eve).
female(kate).

male(bob).
male(carlos).
male(dave).

% mother(_mother, _child).
mother(alice, bob).
mother(kate, alice).

% father(_father, _child)
father(carlos, bob).

child(C, P) :- father(P, C).
child(C, P) :- mother(P, C).

parent(X, Y) :- mother(X, Y).
parent(X, Y) :- father(X, Y).

sister(alice, eve).
sister(eve, alice).
sister(alice, dave).

brother(dave, alice).

% brother(sibling, sibling)
sibling(X, Y) :- brother(X, Y).
sibling(X, Y) :- sister(X, Y).

uncle(U, C) :- sibling(U, PARENT),
child(C, PARENT),
male(U).

relationship(U, C, uncle) :- uncle(U, C).
relationship(P, C, parent) :- parent(P, C).
relationship(B, S, brother) :- brother(B, S).
relationship(G, C, grandparent) :- parent(P, C), parent(G, P).

``````

``relationship(P1, P2, R).``
``````
P1 = dave, P2 = bob, R = uncle ;
P1 = alice, P2 = bob, R = parent ;
P1 = kate, P2 = alice, R = parent ;
P1 = carlos, P2 = bob, R = parent ;
P1 = dave, P2 = alice, R = brother ;
P1 = kate, P2 = bob, R = grandparent ;
false.
``````

It's a powerful tool, if you know how and when to use it. This seems exactly like a place for Prolog. I know it's not terribly popular, or easy to embed, but the impressive feature of wolphram alpha shown in one of the comments can be coded using nothing more than constructs used above, and this is Prolog 101.

-
I actually had taken a look at this "solution" months ago, but in fact this is a very lacking algorithm, able to compute none but the very simplest relationships (sibling, parent, child, uncle). Its method for solving relationships is also quite kludge, rather than computing the relationship, it runs hard-checks for every possible relationship. I need a much more robust solution than that. –  defines Jul 6 '09 at 16:50
I don't think that accusing people of stealing is a good strategy to get help. I've coded a basic prolog example used in almost every book/tutorial ever created, it's like accusing someone of stealing bubble sort. Just to let you know, Prolog is perfectly capable of expressing insanely complicated relationships, and there are ways to compute relationship databases more efficiently than presented naive solution. –  Wojciech Bederski Jul 6 '09 at 17:31
@Wuub my apology if that is the case - I am not well versed in Prolog but did find that exact example in only one place (and I searched for other examples, no luck). My solution is naive, admittedly, but it is much more optimal than the example you presented, both in optimal running time and the robustness of the algorithm. Please, you don't need to take these things seriously. It's programming, we're all learning here and (hopefully) always will be. –  defines Jul 6 '09 at 17:34
-seriously +personally is what I meant –  defines Jul 6 '09 at 17:35
Also, just to clear up any possible confusion, I was addressing the presented algorithm, not PROLOG itself, which actually seems very well suited for the problem at hand as it is engineered specifically to process complex relationships. –  defines Jul 6 '09 at 17:38