Flow in Games provides quite an adventure in gaming. It is no secret that I am not a big player of mainstream console and computer games, and games like Flow confirm that I am not missing out. The combination of visual, aural, and tactical elements creates quite a pleasant experience. I hardly noticed that I had wasted three hours playing! The rules are simple (like most fun games) – eat and evolve, kill or be killed. I think this is a great game for kids because it has a requires some anticipation and coordination skills to time attacks and stirke at the food. I know many more of my hours will be spent playing.
Archive for the ‘Geekdom’ Category
Crazy addictive game
Sunday, February 4th, 2007Futuristic interaction with computers…now!
Sunday, January 21st, 2007E-99: 31-40
Sunday, January 7th, 2007Right on the heals of 21-30 comes 31-40. These problems began to delve into mathematics, with a great emphasis on prime numbers and their generation. Quite interesting to work with, since prime numbers are the basis behind encryption of any non-trivial strength. Enjoy:
%% Determine whether a given integer number is prime.
%% Example: (is-prime 7) -> T
p31(2) -> true;
p31(N) when N rem 2 =:= 0 -> false;
p31(N) -> p31is_prime(N, 3, N div 2 ).p31is_prime(_N, K, Limit) when K > Limit -> true;
p31is_prime(N, K, Limit) ->
case N rem K of
0 -> false;
_Else -> p31is_prime(N, K+2, Limit)
end.%% Determine the greatest common divisor of two positive integer numbers.
%% Use Euclid’s algorithm.
%% Example: (gcd 36 63) -> 9
p32(A, 0) -> A;
p32(A, B) when B > A -> p32(B, A);
p32(A, B) -> p32(B, A rem B).%% Determine whether two positive integer numbers are coprime.
%% Two numbers are coprime if their greatest common divisor equals 1.
%% Example: (coprime 35 64) -> T
p33(A, B) -> p32(A, B) =:= 1.%% Calculate Euler’s totient function phi(m).
%% Euler’s so-called totient function phi(m) is defined as the number of positive integers r (1 < = r < m) that are coprime to m.
%% Example: m = 10: r = 1,3,7,9; thus phi(m) = 4. Note the special case: phi(1) = 1.
%% (totient-phi 10) -> 4
%% Find out what the value of phi(m) is if m is a prime number.
%% psuedo-code if is_prime(m), phi(m) = m-1, else compute phi(m).
%% Euler’s totient function plays an important role in one of the most widely used public key cryptography methods (RSA).
%% In this exercise you should use the most primitive method to calculate this function (there are smarter ways that we shall discuss later).
p34(1) -> 1;
p34(M) -> p34totient_phi(M, 1, []).p34totient_phi(M, M, L) -> length(L);
p34totient_phi(M, R, L) ->
case p33(M, R) of
true -> p34totient_phi(M, R+1, [R | L]);
false -> p34totient_phi(M, R+1, L)
end.%% Determine the prime factors of a given positive integer.
%% Construct a flat list containing the prime factors in ascending order.
%% Example: (prime-factors 315) -> (3 3 5 7)
p35(N) -> p35prime_factors(N, 2, []).p35prime_factors(1, _C, PF) -> lists:reverse(PF);
p35prime_factors(N, 2, PF) ->
case (N rem 2) =:= 0 of
true -> p35prime_factors(N div 2, 2, [2 | PF]);
false -> p35prime_factors(N, 3, PF)
end;
p35prime_factors(N, C, PF) ->
case (N rem C) =:= 0 of
true -> p35prime_factors(N div C, C, [C | PF]);
false -> p35prime_factors(N, C+2, PF)
end.%% Determine the prime factors of a given positive integer (2).
%% Construct a list containing the prime factors and their multiplicity.
%% Example: (prime-factors-mult 315) -> ((3 2) (5 1) (7 1))
%% Hint: The problem is similar to problem P13.
p36(N) -> p10(p35(N)).%% Calculate Euler’s totient function phi(m) (improved).
%% See problem P34 for the definition of Euler’s totient function.
%% If the list of the prime factors of a number m is known in the form of problem P36 then the function phi(m) can be efficiently calculated as follows:
%% Let ((p1 m1) (p2 m2) (p3 m3) …) be the list of prime factors (and their multiplicities) of a given number m. Then phi(m) can be calculated with the following formula:
%% phi(m) = (p1 – 1) * [p1 ** (m1 - 1)] * (p2 – 1) * [p2 ** (m2 - 1)] * (p3 – 1) * [p3 ** (m3 - 1)] + …
%% Note that a ** b stands for the b’th power of a.
p37(M) -> p37phi(p36(M), 1).p37phi([], Phi) -> Phi;
p37phi([[M, P] | L], Phi) -> p37phi(L, Phi * (P – 1) * round(math:pow( P, M-1 )) ).%% Compare the two methods of calculating Euler’s totient function.
%% Use the solutions of problems P34 and P37 to compare the algorithms. Take the number of logical inferences as a measure for efficiency. Try to calculate phi(10090) as an example.
p38(M) ->
{T34, V34} = timer:tc(lp, p34, [M]),
{T37, V37} = timer:tc(lp, p37, [M]),
io:fwrite(“p34 took ~p micro seconds and returned ~p.~n”, [T34, V34]),
io:fwrite(“p37 took ~p micro seconds and returned ~p.~n”, [T37, V37]).%% A list of prime numbers.
%% Given a range of integers by its lower and upper limit, construct a list of all prime numbers in that range.
p39(High) -> p39(1, High).
p39(Low, High) when Low > High -> p39(High, Low);
p39(Low, High) -> [X || X < - p39primes(lists:seq(2, High) , [1]), X >= Low, X =< High].p39primes([], Primes) -> lists:reverse(Primes);
p39primes([1 | Sieve], Primes) -> p39primes(Sieve, [1 | Primes]); % pops 1 off the sieve
p39primes([2 | Sieve], Primes) -> p39primes([X || X < - Sieve, (X rem 2) > 0], [2 | Primes]); % pops 2 off the sieve and removes all multiples of 2
p39primes([Curr | Sieve], Primes) -> p39primes([X || X < - Sieve, (X rem Curr) > 0], [Curr | Primes]). % pops the next value off the sieve and removes all multiples%% Goldbach’s conjecture.
%% Goldbach’s conjecture says that every positive even number greater than 2 is the sum of two prime numbers.
%% Example: 28 = 5 + 23. It is one of the most famous facts in number theory that has not been proved to be correct in the general case.
%% It has been numerically confirmed up to very large numbers (much larger than we can go with our Prolog system).
%% Write a predicate to find the two prime numbers that sum up to a given even integer.
%% Example: (goldbach 28) -> (5 23)
p40(N) -> p40goldbach(N, p39(N), []).p40goldbach(0, _Primes, Result) when length(Result) =:= 2 -> lists:reverse(Result);
p40goldbach(N, _Primes, Result) when length(Result) =:= 2, N =/= 0 -> false;
p40goldbach(_N, [], _Result) -> false;p40goldbach(N, [P | Primes], Result) ->
Sol = p40goldbach(N-P, Primes, [P | Result]),
case is_list(Sol) of
true -> Sol;
_else -> p40goldbach(N, Primes, Result)
end.
E-99: 21-30
Sunday, January 7th, 2007The next installment of the 99 Lisp problems. 27 and 28 are incomplete as I have not sat down to actually work through them yet. More research is needed to do multinomial coefficients. This batch of problems posed some challenge and required a bit of research and dusting off math skills, as well as getting familiar with Erlang’s List Comprehension syntax. For your viewing pleasure:
%% Insert an element at a given position into a list.
%% Example: (insert-at ‘alfa ‘(a b c d) 2) -> (A ALFA B C D)
p21(Elem, L, Pos) -> p21insert(Elem, L, Pos, []).p21insert(Elem, L, 1, NewL) -> lists:reverse([Elem | NewL]) ++ L;
p21insert(Elem, [H | L], Pos, NewL) -> p21insert(Elem, L, Pos-1, [H | NewL]).%% Create a list containing all integers within a given range.
%% If first argument is smaller than second, produce a list in decreasing order.
%% Example: (range 4 9) -> (4 5 6 7 8 9)
p22(Start, End) when Start < End -> p22range_asc(End-Start, [Start]);
p22(Start, End) -> p22range_desc(Start-End, [Start]).p22range_asc(0, L) -> lists:reverse(L);
p22range_asc(Count, [H | L]) -> p22range_asc(Count-1, [H+1, H | L]).p22range_desc(0, L) -> lists:reverse(L);
p22range_desc(Count, [H | L]) -> p22range_desc(Count-1, [H-1, H | L]).%% Extract a given number of randomly selected elements from a list.
%% The selected items shall be returned in a list.
%% Example: (rnd-select ‘(a b c d e f g h) 3) -> (E D A)
%% Hint: Use the built-in random number generator and the result of problem P20.
p23(L, Count) when length(L) < Count -> p23rnd_select(L, length(L), []);
p23(L, Count) -> p23rnd_select(L, Count, []).p23rnd_select(_L, 0, RandL) -> RandL;
p23rnd_select(L, Count, RandL) ->
Rnd = random:uniform(length(L)),
V = lists:nth(Rnd, L),
p23rnd_select(p20(L, Rnd), Count-1, [V | RandL]).%% Lotto: Draw N different random numbers from the set 1..M.
%% The selected numbers shall be returned in a list.
%% Example: (lotto-select 6 49) -> (23 1 17 33 21 37)
%% Hint: Combine the solutions of problems P22 and P23.
p24(Num, High) -> p23(p22(1, High), Num).%% Generate a random permutation of the elements of a list.
%% Example: (rnd-permu ‘(a b c d e f)) -> (B A D C E F)
%% Hint: Use the solution of problem P23.
p25(L) -> p23(L, length(L)).%% Generate the combinations of K distinct objects chosen from the N elements of a list
%% In how many ways can a committee of 3 be chosen from a group of 12 people? We all know that there are C(12,3) = 220 possibilities (C(N,K) denotes the well-known binomial coefficients).
%% For pure mathematicians, this result may be great. But we want to really generate all the possibilities in a list.
%% Example: (combination 3 ‘(a b c d e f)) -> ((A B C) (A B D) (A B E) … )% Not the most efficient way, but generate the power set for the list and remove all but the sub-lists of length K
powerset([]) ->
[[]];
powerset([H | T]) ->
SubPS = powerset(T),
lists:append(SubPS, lists:map(fun(E) -> [H | E] end, SubPS)).p26(K, L) -> [X || X < - powerset(L), length(X) == K].
%% Group the elements of a set into disjoint subsets.
%% a) In how many ways can a group of 9 people work in 3 disjoint subgroups of 2, 3 and 4 persons? Write a function that generates all the possibilities and returns them in a list.
%% Example: (group3 ‘(aldo beat carla david evi flip gary hugo ida)) -> ( ( (ALDO BEAT) (CARLA DAVID EVI) (FLIP GARY HUGO IDA) ) … )
p27([]) -> [].%% b) Generalize the above predicate in a way that we can specify a list of group sizes and the predicate will return a list of groups.
%% Example: (group ‘(aldo beat carla david evi flip gary hugo ida) ‘(2 2 5)) -> ( ( (ALDO BEAT) (CARLA DAVID) (EVI FLIP GARY HUGO IDA) ) … )
%% Note that we do not want permutations of the group members; i.e. ((ALDO BEAT) …) is the same solution as ((BEAT ALDO) …).
%% However, we make a difference between ((ALDO BEAT) (CARLA DAVID) …) and ((CARLA DAVID) (ALDO BEAT) …).
%% You may find more about this combinatorial problem in a good book on discrete mathematics under the term “multinomial coefficients”.
p28() -> [].%% Sorting a list of lists according to length of sublists
%% a) We suppose that a list contains elements that are lists themselves. The objective is to sort the elements of this list according to their length. E.g. short lists first, longer lists later, or vice versa.
%% Example: (lsort ‘((a b c) (d e) (f g h) (d e) (i j k l) (m n) (o))) -> ((O) (D E) (D E) (M N) (A B C) (F G H) (I J K L))
p29(L) -> p29lsort(L).%% code taken from Erlang Programming Examples -> List Comprehensions -> QuickSort and adapted
p29lsort([]) -> [];
p29lsort([Pivot | L]) ->
p29lsort([ X || X < - L, length(X) < length(Pivot)]) ++ [Pivot | p29lsort([ X || X <- L, length(X) >= length(Pivot)])].%% b) Again, we suppose that a list contains elements that are lists themselves. But this time the objective is to sort the elements of this list according to their length frequency;
%% i.e., in the default, where sorting is done ascendingly, lists with rare lengths are placed first, others with a more frequent length come later.
%% Example: (lfsort ‘((a b c) (d e) (f g h) (d e) (i j k l) (m n) (o))) -> ((i j k l) (o) (a b c) (f g h) (d e) (d e) (m n))
%% Note that in the above example, the first two lists in the result have length 4 and 1, both lengths appear just once. The third and forth list have length 3 which appears twice (there are two list of this length).
%% And finally, the last three lists have length 2. This is the most frequent length.
p30(L) -> p30lfsort(L).p30lfsort([]) -> [];
p30lfsort([H | L]) ->
Grouped = p30group(L, [[H]]),
Sorted = p29(Grouped),
p30ungroup(Sorted, []).p30group([], Grouped) -> Grouped;
p30group([H | L], Grouped) -> p30group(L, p30insert(H, Grouped, [])).%% insert Elem in to a group with the same length, or create a new group for the length of Elem
p30insert(Elem, [], PrevGroups) ->
lists:reverse([[Elem] | PrevGroups]);
p30insert(Elem, [ [GroupH | GroupT] | RestGrouped], PrevGroups) when length(GroupH) == length(Elem) ->
PrevGroups ++ [ [GroupH, Elem | GroupT] | RestGrouped];
p30insert(Elem, [ [GroupH | GroupT] | RestGrouped], PrevGroups) ->
p30insert(Elem, RestGrouped, [[GroupH | GroupT] | PrevGroups]).%% remove length-specific groupings
p30ungroup([], Ungrouped) -> lists:reverse(Ungrouped);
p30ungroup([H | L], Ungrouped) when not is_list(H) -> [[H | L] | Ungrouped];
p30ungroup([Group | L], Ungrouped) -> p30ungroup(Group, []) ++ p30ungroup(L, Ungrouped).
The Importance of good algorithm design
Saturday, January 6th, 2007Working through the 99 Lisp Problems in Erlang and just did a comparison of two different methods for computing Euler’s totient function. The results:
> lp:p39(10090).
p34 took 10864 micro seconds and returned 4032.
p37 took 72 micro seconds and returned 4032.
I’ll leave it to the reader to work the problems themselves, but it does illustrate the importance of good algorithm design in mission-critical parts of your code. Were my application’s lifeblood to be in calculating phi, and I was naive and took the p34 algorithm to solve for phi, I would be 150x slower at doing the job. I guess the moral is, always research mission-critical portions of code for optimized algorithms. A sub-moral would be to keep abreast of the latest and greatest in algorithms and math in general. I like to have a friend in grad school studying quantum mechanics to keep me informed!
E-99: 11-20
Friday, December 22nd, 2006The second set of 10 problems are now in the bag. Feeling the Erlang-fu! The first set can be found here.
%% Modified run-length encoding.
%% Modify the result of problem P10 in such a way that if an element has no duplicates it is simply copied into the result list.
%% Only elements with duplicates are transferred as (N E) lists.
%% Example: (encode-modified ‘(a a a a b c c a a d e e e e)) -> ((4 A) B (2 C) (2 A) D (4 E))
p11([]) -> [];
p11(L) -> p11encode(p09(L), []).p11encode([], Encoded) -> lists:reverse(Encoded);
p11encode([[Elem | SubL] | L], Encoded) ->
case length(SubL) of
0 -> p11encode(L, [Elem | Encoded]);
_Else -> p11encode(L, [[length(SubL)+1, Elem] | Encoded])
end.%% Decode a run-length encoded list.
%% Given a run-length code list generated as specified in problem P11. Construct its uncompressed version.
p12([]) -> [];
p12(L) -> p12decode(L, []).p12decode([], Decoded) -> lists:reverse(Decoded);
p12decode([[N, Elem] | L], Decoded) -> p12decode(L, lists:duplicate(N, Elem) ++ Decoded);
p12decode([Elem | L], Decoded) -> p12decode(L, [Elem | Decoded]).%% Run-length encoding of a list (direct solution).
%% Implement the so-called run-length encoding data compression method directly.
%% I.e. don’t explicitly create the sublists containing the duplicates, as in problem P09, but only count them.
%% As in problem P11, simplify the result list by replacing the singleton lists (1 X) by X.
%% Example: (encode-direct ‘(a a a a b c c a a d e e e e)) -> ((4 A) B (2 C) (2 A) D (4 E))
p13([]) -> [];
p13([H | L]) -> p13encode(L, H, 1, []).%% p13encode(The Remaining List,
%% The Current Element,
%% The Number Of Repetitions Thus Far,
%% The Encoded List Thus Far)
p13encode([], Curr, Rep, Encoded) ->
case Rep of
1 -> lists:reverse([Curr | Encoded]);
_Else -> lists:reverse([[Rep, Curr] | Encoded])
end;
p13encode([H | L], Curr, Rep, Encoded) ->
case H of
Curr -> p13encode(L, Curr, Rep+1, Encoded);
_Else ->
case Rep of
1 -> p13encode(L, H, 1, [Curr | Encoded]);
_Other -> p13encode(L, H, 1, [[Rep, Curr] | Encoded])
end
end.%% Duplicate the elements of a list.
%% Example: (dupli ‘(a b c c d)) -> (A A B B C C C C D D)
p14([]) -> [];
p14([H | L]) -> p14duplicate(L, [H, H]).p14duplicate([], Cloned) -> lists:reverse(Cloned);
p14duplicate([H | L], Cloned) -> p14duplicate(L, [H, H | Cloned]).%% Replicate the elements of a list a given number of times.
%% Example: (repli ‘(a b c) 3) -> (A A A B B B C C C)
p15([], _Num) -> [];
p15([H | L], Reps) -> p15replicate(L, Reps, [lists:duplicate(Reps, H)]).p15replicate([], _Reps, Replicated) -> lists:append(lists:reverse(Replicated));
p15replicate([H | L], Reps, Replicated) -> p15replicate(L, Reps, [lists:duplicate(Reps, H) | Replicated]).%% Drop every N’th element from a list.
%% Example: (drop ‘(a b c d e f g h i k) 3) -> (A B D E G H K)
p16([], _Nth) -> [];
p16([H | L], Nth) -> p16drop(L, Nth, Nth-1, [H]).p16drop([], _Nth, _Curr, Dropped) -> lists:reverse(Dropped);
p16drop([_H | L], Nth, Curr, Dropped) when Curr == 1 -> p16drop(L, Nth, Nth, Dropped);
p16drop([H | L], Nth, Curr, Dropped) -> p16drop(L, Nth, Curr-1, [H | Dropped]).%% Split a list into two parts; the length of the first part is given.
%% Do not use any predefined predicates.
%% Example: (split ‘(a b c d e f g h i k) 3) -> ( (A B C) (D E F G H I K))
p17([], _SplitPoint) -> [];
p17(L, SplitPoint) -> p17split(L, SplitPoint, []).p17split([], _SplitPoint, List) -> lists:reverse(List);
p17split(L, SplitPoint, Head) when SplitPoint == 0 -> [lists:reverse(Head) | [L]];
p17split([H | L], SplitPoint, Head) -> p17split(L, SplitPoint-1, [H | Head]).%% Extract a slice from a list.
%% Given two indices, I and K, the slice is the list containing the elements
%% between the I’th and K’th element of the original list (both limits included).
%%Start counting the elements with 1.
%% Example: (slice ‘(a b c d e f g h i k) 3 7) -> (C D E F G)
p18([], _Start, _End) -> [];
p18(L, Start, End) -> p18slice(L, Start, End-Start, []).p18slice([], _Start, _Count, Sliced) -> lists:reverse(Sliced);
p18slice([H | _L], 1, 0, Sliced) -> lists:reverse([H | Sliced]);
p18slice([H | L], 1, Count, Sliced) -> p18slice(L, 1, Count-1, [H | Sliced]);
p18slice([_H | L], Start, Count, Sliced) -> p18slice(L, Start-1, Count, Sliced).%% Rotate a list N places to the left.
%% Examples: (rotate ‘(a b c d e f g h) 3) -> (D E F G H A B C)
%% (rotate ‘(a b c d e f g h) -2) -> (G H A B C D E F)
%% Hint: Use the predefined functions length and append, as well as the result of problem P17.
p19([], _Rotate) -> [];
p19(L, Rotate) ->
case Rotate of
Point when Rotate > 0 -> Point;
_LT0 -> Point = length(L) + Rotate
end,
[F, B] = lp:p17(L, Point),
B ++ F.%% Remove the K’th element from a list.
%% Example: (remove-at ‘(a b c d) 2) -> (A C D)
p20([], _Point) -> [];
p20(L, Point) -> p20remove(L, Point, []).p20remove([], _Point, BeforePoint) -> lists:reverse(BeforePoint);
p20remove([_H | L], 1, BeforePoint) -> lists:reverse(BeforePoint) ++ L;
p20remove([H | L], Point, BeforePoint) -> p20remove(L, Point-1, [H | BeforePoint]).
E-99: 1-10
Wednesday, December 13th, 2006Using the 99 Lisp Problems as a guide, I have been writing the problems in Erlang to grow more comfortable with the non-concurrent aspects of the language. Once completed, the goal is then to add in some concurrency exercises to round out the Erlang experience. I have to say, to this point, I feel I’m beginning to grok the ole Erlang list-handling / pattern-matching capabilities.
<update date=”December 22nd, 2006″> Reading the Erlang efficiency guide I found out that appending lists is not the greatest way to do list creation, so I rewrote the applicable exercises with the suggestion of simply reversing the list at the end.</update>
Here, then, are my solutions to the first ten problems:
%% Find the last box of a list.
%% Example: (my-last ‘(a b c d)) -> (D)
p01(L) when length(L) =< 1 -> L;
p01([_ | L]) -> p01(L).%% Find the last but one box of a list.
%% Example: (my-but-last ‘(a b c d)) -> (C D)
p02(L) when length(L) =< 2 -> L;
p02([_ | L]) -> p02(L).%% Find the K’th element of a list. The first element in the list is number 1.
%% Example: (element-at ‘(a b c d e) 3) -> C
p03([], _) -> [];
p03(_, Pos) when Pos < 1 -> bad_pos;
p03([H | _], 1) -> H;
p03([_ | L], Pos) -> p03(L, Pos-1).%% Find the number of elements of a list.
p04([]) -> 0;
p04(L) -> p04count(L, 0).p04count([], C) -> C;
p04count([_ | L], C) -> p04count(L, C+1).%% Reverse a list.
p05([]) -> [];
p05(L) -> p05reverse(L, []).p05reverse([], RevL) -> RevL;
p05reverse([H | L], RevL) -> p05reverse(L, [H | RevL]).%% Find out whether a list is a palindrome. A palindrome can be read forward or backward; e.g. (x a m a x).
p06([]) -> true;
p06(L) when length(L) == 1 -> true;
p06(L) -> L == p05(L).%% Flatten a nested list structure. Transform a list, possibly holding lists as elements into a `flat’ list by replacing each list with its elements (recursively).
%% Example: (my-flatten ‘(a (b (c d) e))) -> (A B C D E)
%% Hint: Use the predefined functions list and append.
p07([]) -> [];
p07(L) when not is_list(L) -> [L];
p07([H | L]) ->
Head = p07(H),
Tail = p07(L),
Head ++ Tail.%% Eliminate consecutive duplicates of list elements.
%% If a list contains repeated elements they should be replaced with a single copy of the element. The order of the elements should not be changed.
%% Example: (compress ‘(a a a a b c c a a d e e e e)) -> (A B C A D E)
p08([]) -> [];
p08([H | L]) -> p08compress(L, H, [H]).p08compress([], _Curr, Compressed) -> lists:reverse(Compressed);
p08compress([H | L], Curr, Compressed) ->
case Curr of
H -> p08compress(L, Curr, Compressed);
_Else -> p08compress(L, H, [H | Compressed])
end.%% Pack consecutive duplicates of list elements into sublists. If a list contains repeated elements they should be placed in separate sublists.
%% Example: (pack ‘(a a a a b c c a a d e e e e)) -> ((A A A A) (B) (C C) (A A) (D) (E E E E))
p09([]) -> [];
p09([H | L]) -> p09pack(L, H, [H], []).p09pack([], _Curr, SubL, Packed) -> lists:reverse([SubL | Packed]);
p09pack([H | L], Curr, SubL, Packed) ->
case Curr of
H -> p09pack(L, Curr, [H | SubL], Packed);
_Else -> p09pack(L, H, [H], [SubL | Packed])
end.%% Run-length encoding of a list.
%% Use the result of problem P09 to implement the so-called run-length encoding data compression method.
%% Consecutive duplicates of elements are encoded as lists (N E) where N is the number of duplicates of the element E.
%% Example: (encode ‘(a a a a b c c a a d e e e e)) -> ((4 A) (1 B) (2 C) (2 A) (1 D)(4 E))
p10([]) -> [];
p10(L) -> p10encode(p09(L), []).p10encode([], Encoded) -> lists:reverse(Encoded);
p10encode([[Elem | SubL] | L], Encoded) -> p10encode(L, [[length(SubL)+1, Elem] | Encoded]).
Those who grok Erlang and happen to find this blog, please feel free to offer criticism of my implementations.
Get A Life
Wednesday, November 15th, 2006Holy ballz this guy needs a job or something. Still cool what he does with dice.
Who Needs Free Time
Tuesday, November 7th, 2006Eat it Cingular
Thursday, October 26th, 2006I don’t know why, but Cingular apparently does not want me paying my bill. When I log into my account to pay online, I was taken to an intermediate page where I was asked, in a mandatory fashion, for my email address. I’m not a big fan of giving that sucker out for no reason, so I simply clicked the ‘Continue’ button. Unfortunately, the button was a link whose href was the lovely octothorpe.
This of course meant I was going nowhere by means of that button. I was quite peeved at this point because, not only did I not get an explanation from the page telling my why my email was required, but I also had no explanation for why the continue button failed to do so. The age-old adage, “Fail to communicate with me properly once, you suck; fail twice, now I’m pissed” came to mind.
So what’s a web geek to do? Obviously search the page’s javascript for the form submission line and execute it directly through Firebug commandline! Should any Cingular users get frustrated as well, get Firebug (and Firefox, which I have to mention since Google Analytics tells me the internets are alive with IE users still – shame on you all), and execute this line of code:
document.updateRequiredRegisteredInfoActionForm.submit();
Not only did this forward me on to my account page, but it also bypassed the need to fill in my email for no good reason. I get enough spam as it is. So there it is my friends; simple, one-liner to defeat Cingular’s attempts to be poor communicators. A silver lining here, besides getting in, is the lesson learned from Cingular’s mistake: Don’t suck at communicating with your users!
So long, and thanks for all the fish.