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crc_aided_list_decode.m
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crc_aided_list_decode.m
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%decodes the received message using list decoding
%received: (Nx1) matrix, represents the received message
%crc_polynomial: (rx1) matrix, represents the CRC polynomial
%frozen_indices: ((N-K)x1) matrix, specifies the indices of the frozen bits
%frozen_bits: ((N-K)x1) matrix, specifies the values of the frozen bits
%list_size: the number of paths to maintain
%channel_type: specifies the type of the channel on which the bits were
%sent. Could be 'bsc' for Binary Symmetric Channel, 'bec' for
%Binary Erasure Channel, and 'awgn' for Additive White Gaussian Noise
%Channel
%param: in 'bsc', param specifies the probability of the bit getting
%flipped, in 'bec', it represents the probability of erasure, and in 'awgn'
%it represents the standard deviation of the distribution
function result = crc_aided_list_decode(received, crc_polynomial, frozen_indices, frozen_bits, channel_type, param, list_size)
length = size(received, 1);
%We create 2*L path containers. However, whenever the number actually
%reaches 2*L, we trim half of them and keep only L
paths(list_size*2) = list_decoding_path();
%We start by initializing storage elements for the first path to hold our intermediate
%results. One of them will hold intermediate likelihoods of elements in
%the middle to be a 0. The other holds the value of intermediate xor
%operations that have already been calculated
paths(1).likelihoods = cell(log2(length) + 1);
paths(1).xors = cell(log2(length));
for i = 1:(log2(length)+1)
paths(1).likelihoods{i} = NaN(length/(2^(i-1)), 2^(i-1));
end
for i = 1:log2(length)
paths(1).xors{i} = NaN(length/(2^(i-1)), 2^(i-1));
end
%We bit reverse the frozen indices. This is because frozen_indices
%specifies which actual indices are frozen, but here we are working in a
%bit reversed order, so we reverse frozen_indices to correspond to what
%we are working with
reversed_frozen_indices = zeros(size(frozen_indices, 1), 1);
for i = 1:size(frozen_indices, 1)
reversed_frozen_indices(i, 1) = reverse_index(frozen_indices(i), log2(length));
end
paths(1).results = NaN(size(received, 1), 1);
paths(1).alive = true;
paths(1).path_likelihood = 1;
%For each path that we have, we go and calculate the likelihoods.
%Then, if the bit is frozen, we set it and move on
%If it is not frozen, we create 2 paths from each path with the two
%possibilities, and then check, if we have surpassed the list size, we
%trim.
%Then, for each path that we have, we propagate the xors
for i = 1:size(received, 1)
l = zeros(list_size*2, 1);
for j = 1:list_size*2
if (paths(j).alive == true)
[l(j), paths(j).likelihoods] = calculate_likelihood(received, (paths(j).likelihoods), (paths(j).xors), 1, i, 1, log2(length) + 1, channel_type, param);
end
end
frozen = find(reversed_frozen_indices == i);
if (~isempty(frozen))
for j = 1:list_size*2
if (paths(j).alive == true)
paths(j).results(i) = frozen_bits(frozen(1));
end
end
else
newly_created_paths = [];
for j = 1:list_size*2
if (paths(j).alive == true)
if (l(j) > 1)
paths(j).results(i) = 0;
new_path_likelihood = 1/l(j);
else
paths(j).results(i) = 1;
new_path_likelihood = l(j);
end
%We create another path
%Look for a dead path
for k = 1:list_size*2
if (paths(k).alive == false && ~any(newly_created_paths(:) == k))
paths(k).path_likelihood = new_path_likelihood;
paths(j).path_likelihood = 1 / new_path_likelihood;
paths(k).likelihoods = paths(j).likelihoods;
paths(k).xors = paths(j).xors;
paths(k).results = paths(j).results;
paths(k).results(i) = ~paths(j).results(i);
newly_created_paths = [newly_created_paths k];
break;
end
end
end
end
for j = newly_created_paths
paths(j).alive = true;
end
%if we have more than list_size alive paths, we will have to prune
count = 0;
for j = 1:list_size*2;
if (paths(j).alive == true)
count = count + 1;
end
end
if (count > list_size)
% we remove half of the paths
% note: here, this algorithm is wrong if list_size is not a power
% of two.
for j = 1:list_size
min = 1;
for k = 1:list_size*2
if (paths(k).alive == true)
if (paths(k).path_likelihood < paths(min).path_likelihood)
min = k;
end
end
end
paths(min).alive = false;
end
end
end
for j = 1:list_size*2
if (paths(j).alive == true)
paths(j).xors = propagate_value(paths(j).results(i), paths(j).xors, 1, i, 1, log2(length) + 1);
end
end
end
information_indices = setdiff(transpose(1:length), frozen_indices);
crc_size = size(crc_polynomial, 1) - 1;
for k = 1:list_size*2
if (paths(k).alive == true)
paths(k).results = bitrevorder(paths(k).results);
message = paths(k).results(information_indices);
crc = calculate_crc(message(1:end-crc_size), crc_polynomial, message(end-crc_size + 1:end));
if (~isempty(find(crc, 1))) %not all zeros
paths(k).alive = false;
end
end
end
count = 0;
for k = 1:list_size*2
if (paths(k).alive == true)
count = count + 1;
end
end
disp('number of paths where crc is correct: ');
disp(count);
%We now choose the path that has the highest likelihood, that passes the
%CRC check
max = -1;
for k = 1:list_size*2
if (paths(k).alive == true)
if (max == -1)
max = k;
else
if (paths(k).path_likelihood >= paths(max).path_likelihood)
max = k;
end
end
end
end
if (max ~= -1)
result = paths(max).results;
else
result(1:length, 1) = -1;
end
end
%calculates the likelihood of the bit at a specific level to be a zero, and
%updates the likelihood table accordingly
function [likelihood, storage] = calculate_likelihood(received, likelihoods, xors, layer, idx1, idx2, max_depth, channel_type, param, original)
%if a value has already been calculated, return
if (~isnan(likelihoods{layer}(idx1, idx2)))
likelihood = likelihoods{layer}(idx1, idx2);
storage = likelihoods;
return;
end
%If we have reached the channel level, get the likelihood from the
%channel and return
if (layer == max_depth)
l = get_channel_likelihood(received(reverse_index(idx2, log2(size(received, 1)))), channel_type, param);
likelihood = l;
likelihoods{layer}(idx1, idx2) = l;
storage = likelihoods;
return;
end
[l1, likelihoods] = calculate_likelihood(received, likelihoods, xors, layer+1, (floor((idx1 - 1)/2)) + 1, (2*(idx2 - 1)) + 1, max_depth, channel_type, param);
[l2, likelihoods] = calculate_likelihood(received, likelihoods, xors, layer+1, (floor((idx1 - 1)/2)) + 1, (2*(idx2 - 1) + 1) + 1, max_depth, channel_type, param);
%BEC requires special treatment because it haas zeroes and infinities
if (mod(idx1 - 1, 2) == 0)
if (strcmp(channel_type, 'bec'))
if ((isinf(l1) && isinf(l2)) || (l1 == 0 && l2 == 0))
likelihood = Inf;
elseif ((isinf(l1) && l2 == 0) || (l1 == 0 && isinf(l2)))
likelihood = 0;
else
likelihood = 1;
end
else
likelihood = (l1*l2 + 1)/(l1 + l2);
end
else
if (strcmp(channel_type, 'bec'))
if (l2 ~= 1)
likelihood = l2;
elseif (l1 ~= 1)
likelihood = xor(l1, xors{layer}(idx1 - 1, idx2));
else
likelihood = 1;
end
else
if (xors{layer}(idx1 - 1, idx2) == 0)
likelihood = l1*l2;
else
likelihood = l2/l1;
end
end
end
likelihoods{layer}(idx1, idx2) = likelihood;
storage = likelihoods;
end
function likelihood = get_channel_likelihood(value, channel_type, param)
if (strcmp(channel_type, 'bsc'))
likelihood = get_bsc_likelihood(value, param);
elseif (strcmp(channel_type, 'bec'))
likelihood = get_bec_likelihood(value);
elseif (strcmp(channel_type, 'awgn'))
likelihood = get_awgn_likelihood(value, param);
end
end
function likelihood = get_bsc_likelihood(value, flip_probability)
if (value == 0)
likelihood = (1-flip_probability)/flip_probability;
else
likelihood = flip_probability/(1-flip_probability);
end
end
function likelihood = get_bec_likelihood(value)
if (value == 0)
likelihood = Inf;
elseif (value == 1)
likelihood = 0;
else
likelihood = 1;
end
end
function likelihood = get_awgn_likelihood(value, sigma)
likelihood = exp((-(value+1)^2/(2*sigma^2)))/exp((-(value-1)^2/(2*sigma^2)));
end
function reversed_index = reverse_index(idx, n)
reversed_index = bin2dec(fliplr(dec2bin(idx - 1,n))) + 1;
end
%propagates the xor values and updates the xor table accordingly
function new_values = propagate_value(value, xors, layer, idx1, idx2, max_depth)
xors{layer}(idx1, idx2) = value;
if (layer == max_depth)
new_values = xors;
return;
end
if (mod(idx1 - 1, 2) == 0)
new_values = xors;
return;
end
xors = propagate_value(xor(value, xors{layer}(idx1-1, idx2)), xors, layer+1, (floor((idx1 - 1)/2)) + 1, 2*(idx2 - 1) + 1, max_depth);
xors = propagate_value(value, xors, layer+1, (floor((idx1 - 1)/2)) + 1, (2*(idx2 - 1) + 1) + 1, max_depth);
new_values = xors;
end