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default.py
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default.py
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from datetime import datetime
from Chamaeleo.methods.inherent import index_base, base_index
from Chamaeleo.utils.monitor import Monitor
class AbstractCodingAlgorithm(object):
def __init__(self, need_logs):
self.bit_size = None
self.need_logs = need_logs
self.monitor = Monitor()
self.segment_length = None
def __init_check__(self):
raise NotImplementedError("\"init_check\" interface needs to be implemented!")
def silicon_to_carbon(self, bit_segments, bit_size):
for bit_segment in bit_segments:
if type(bit_segment) != list or type(bit_segment[0]) != int:
raise ValueError("The dimension of bit matrix can only be 2!")
if self.need_logs:
print("The bit size of the encoded file is " + str(self.bit_size) + " bits and"
+ " the length of final encoded binary segments is " + str(self.segment_length))
self.bit_size = bit_size
self.segment_length = len(bit_segments[0])
start_time = datetime.now()
if self.need_logs:
print("Encode bit segments to DNA sequences by coding scheme.")
dna_sequences = self.encode(bit_segments)
encoding_runtime = (datetime.now() - start_time).total_seconds()
nucleotide_count = 0
for dna_sequence in dna_sequences:
nucleotide_count += len(dna_sequence)
information_density = bit_size / nucleotide_count
return {"dna": dna_sequences, "i": information_density, "t": encoding_runtime}
def carbon_to_silicon(self, dna_sequences):
if self.bit_size is None:
raise ValueError("The parameter \"bit_size\" is needed, "
+ "which guides the number of bits reserved at the end of the digital file!")
if self.segment_length is None:
raise ValueError("The parameter \"segment_length\" is needed, "
+ "which clears the information that may exist in each sequence. "
+ "For example, assuming that the coding scheme requires an even binary segment length, "
+ "if the inputted length is an odd number, a bit [0] is added at the end.")
for dna_sequence in dna_sequences:
if type(dna_sequence) != list or type(dna_sequence[0]) != str:
raise ValueError("The dimension of nucleotide matrix can only be 2!")
start_time = datetime.now()
if self.need_logs:
print("Decode DNA sequences to bit segments by coding scheme.")
bit_segments = self.decode(dna_sequences)
for segment_index, bit_segment in enumerate(bit_segments):
if len(bit_segment) != self.segment_length:
bit_segments[segment_index] = bit_segment[: self.segment_length]
decoding_runtime = (datetime.now() - start_time).total_seconds()
return {"bit": bit_segments, "s": self.bit_size, "t": decoding_runtime}
def encode(self, bit_segments):
raise NotImplementedError("\"decode\" interface needs to be implemented!")
def decode(self, dna_sequences):
raise NotImplementedError("\"decode\" interface needs to be implemented!")
class BaseCodingAlgorithm(AbstractCodingAlgorithm):
def __init__(self, need_logs=False):
super().__init__(need_logs)
self.mapping_rules = [[0, 0], [0, 1], [1, 0], [1, 1]]
def __init_check__(self):
pass
def encode(self, bit_segments):
dna_sequences = []
for segment_index, bit_segment in enumerate(bit_segments):
dna_sequence = []
if len(bit_segment) % 2 != 0:
raise ValueError("The length of inputted binary segment must be divided by 2!")
for position in range(0, len(bit_segment), 2):
dna_sequence.append(index_base.get(self.mapping_rules.index(bit_segment[position: position + 2])))
dna_sequences.append(dna_sequence)
if self.need_logs:
self.monitor.output(segment_index + 1, len(bit_segments))
return dna_sequences
def decode(self, dna_sequences):
bit_segments = []
for sequence_index, dna_sequence in enumerate(dna_sequences):
bit_segment = []
for nucleotide in dna_sequence:
bit_segment += self.mapping_rules[base_index.get(nucleotide)]
bit_segments.append(bit_segment)
if self.need_logs:
self.monitor.output(sequence_index + 1, len(dna_sequences))
return bit_segments
class AbstractErrorCorrectionCode(object):
def __init__(self, need_logs):
self.need_logs = need_logs
self.segment_length = None
self.monitor = Monitor()
def insert(self, bit_segments):
if self.need_logs:
print("Insert the error-correction code to the bit segments.")
verified_bit_segments = []
if type(bit_segments) == list and type(bit_segments[0]) == list:
self.segment_length = len(bit_segments[0])
for index, bit_segment in enumerate(bit_segments):
verified_bit_segments.append(self.insert_one(bit_segment))
if self.need_logs:
self.monitor.output(index + 1, len(bit_segments))
elif type(bit_segments) == list and type(bit_segments[0]) == int:
self.segment_length = len(bit_segments)
verified_bit_segments = self.insert_one(bit_segments)
else:
raise ValueError("The matrix must be 1-dimensional or 2-dimensional, and the value is of type \"int\".")
if self.need_logs:
print("The error-correction code automatically records the original length (" + str(self.segment_length)
+ ") of each binary segment, which provide more information when an error really occurs.")
print("We recommend you save this code through serialized object!")
print("Generally, ignoring it during decoding does not cause more problems.")
return verified_bit_segments, len(verified_bit_segments[0]) - len(bit_segments[0])
def remove(self, verified_bit_segments):
if self.need_logs:
print("Check and remove the error-correction code from the bit segments.")
bit_segments = []
error_bit_segments = []
error_indices = []
if type(verified_bit_segments) == list and type(verified_bit_segments[0]) == list:
error_rate = 0
for index, verified_bit_segment in enumerate(verified_bit_segments):
if verified_bit_segment is not None:
output = self.remove_one(verified_bit_segment)
data, data_type = output.get("data"), output.get("type")
if data_type:
if self.segment_length is not None:
bit_segments.append(data[len(data) - self.segment_length:])
else:
bit_segments.append(data)
else:
error_rate += 1
error_indices.append(index)
error_bit_segments.append(data)
else:
error_rate += 1
error_indices.append(index)
error_bit_segments.append(None)
if self.need_logs:
self.monitor.output(index + 1, len(verified_bit_segments))
error_rate /= len(verified_bit_segments)
elif type(verified_bit_segments) == list and type(verified_bit_segments[0]) == int:
output = self.remove_one(verified_bit_segments[0])
data, data_type = output.get("data"), output.get("type")
if data_type:
error_rate = 0
if self.segment_length is not None:
bit_segments = data[len(data) - self.segment_length:]
else:
bit_segments = data
else:
error_rate = 1
error_indices.append(0)
error_bit_segments.append(data)
else:
raise ValueError("The matrix must be 1-dimensional or 2-dimensional, and the value is of type \"int\".")
return {"bit": bit_segments, "e_r": error_rate, "e_i": error_indices, "e_bit": error_bit_segments}
def insert_one(self, input_list):
raise NotImplementedError("\"insert_one\" interface needs to be implemented!")
def remove_one(self, input_list):
raise NotImplementedError("\"remove_one\" interface needs to be implemented!")