def print_side(orderbook):
if len(orderbook) == 0:
print([])
return
color = Fore.RED if orderbook.side == ASK else Fore.GREEN
_format = color + '{0:>0.2f}' + '{1:>10} {2:>12}'
for count, order in enumerate(
reversed(orderbook[0:10]) if orderbook.side is ASK else orderbook):
print(
_format.format(order.price, truncate(order.amount, 2),
order.total))
if count == 9:
break
def sha1(text):
#Initial Digest in Binary:
h0 = '01100111010001010010001100000001'
h1 = '11101111110011011010101110001001'
h2 = '10011000101110101101110011111110'
h3 = '00010000001100100101010001110110'
h4 = '11000011110100101110000111110000'
numstring=""
chunkwords = []
#1. Take input text and split it into an array of the characters' ASCII codes
asciiText = utils.stringToCharList(text)
asciiList = utils.charToASCII(asciiText)
#2. Convert ASCII codes to binary
#3. Pad zeros to the front of each until they are 8 bits long
binaryAscii = utils.asciiListToBinaryList(asciiList)
paddedBinaryAscii = utils.padZeroList(binaryAscii, 8)
#4. join them together and append a 1
numstring = numstring.join(paddedBinaryAscii) + '1'
#5. pad the binary message with zeros until its length is 512 mod 448
while ( (len(numstring) % 512) != 448):
numstring = numstring + '0'
#6. take binar 8-bit ASCII code array from step 3, get its length in binary
length = ''
length = len(length.join(paddedBinaryAscii) )
binaryLength = bin(length)[2:]
binaryLength = utils.padZeroString(binaryLength, 64)
#8. append to your previously created binary message from step 5
numstring = numstring + binaryLength
#9. break the message into an array of 'chunks' of 512 characters
n = 512
chunks = [numstring[i:i+n] for i in range(0, len(numstring), n)]
#10. break each chunk into a subarray of sixteen 32-bit 'words'
n = 32
for ch in chunks:
chunkwords.append([ch[i:i+n] for i in range(0, len(ch), n)])
#11. loop through each 'chunk' array of sixteen 32-bit 'words' and extend each array to 80 'words' using bitwise operations
word80 = []
for chunk in chunkwords:
for i in range(16, 80):
wordA = chunk[i - 3]
wordB = chunk[i - 8]
wordC = chunk[i - 14]
wordD = chunk[i - 16]
xorA = utils.xOR(wordA, wordB)
xorB = utils.xOR(xorA, wordC)
xorC = utils.xOR(xorB, wordD)
newWord = utils.leftRotate(xorC, 1)
chunk.append(newWord)
word80.append(chunk)
#13. Looping through each chunk: bitwise operatiosn and variable reassignment
for wordArray in word80:
a = h0
b = h1
c = h2
d = h3
e = h4
for j in range (80):
f = ''
k = ''
if j >= 0 and j <= 19:
BandC = utils.andBinStr(b, c)
notB = utils.andBinStr(utils.notBinStr(b, len(b)), d )
f = utils.xOR(BandC, notB)
k = '01011010100000100111100110011001'
elif j >= 20 and j <= 39:
BxorC = utils.xOR(b, c)
f = utils.xOR(BxorC, d)
k = '01101110110110011110101110100001'
elif j >= 40 and j <= 59:
BandC = utils.andBinStr(b, c)
BandD = utils.andBinStr(b, d)
CandD = utils.andBinStr(c, d)
BandCxorBandD = utils.xOR(BandC, BandD)
f = utils.xOR(BandCxorBandD, CandD)
k = '10001111000110111011110011011100'
elif j >= 60 and j <= 79:
BxorC = utils.xOR(b, c)
f = utils.xOR(BxorC, d)
k = '11001010011000101100000111010110'
word = wordArray[j]
tempA = utils.binaryAddition(utils.leftRotate(a,5), f)
tempB = utils.binaryAddition(tempA, e)
tempC = utils.binaryAddition(tempB, k)
temp = utils.binaryAddition(tempC, word)
temp = utils.truncate(temp, 32)
e = d
d = c
c = utils.leftRotate(b, 30)
b = a
a = temp
# Add working elements to the digest after 80 iterations.
# This occurs for each chunk of 512 bits, 80 words
h0 = utils.binaryAddition(h0, a)
h1 = utils.binaryAddition(h1, b)
h2 = utils.binaryAddition(h2, c)
h3 = utils.binaryAddition(h3, d)
h4 = utils.binaryAddition(h4, e)
# Convert Digest to Hex,
h0 = utils.binaryToHex(h0)
h1 = utils.binaryToHex(h1)
h2 = utils.binaryToHex(h2)
h3 = utils.binaryToHex(h3)
h4 = utils.binaryToHex(h4)
#Create the Hash value
hashvalue = h0+h1+h2+h3+h4
#return the hash value.
return hashvalue
def task_finish(self, task):
self._logger.debug('task_finish: ' + truncate(task.__str__()))
self._sample_coll.insert_one(task)
def task_start(self, task):
self._logger.debug('task_start: ' + truncate(task.__str__()))
def taskset_stop(self, taskset):
self._logger.debug('Taskset_stop: ' + truncate(taskset.__str__()))
def taskset_finish(self, taskset):
self._logger.debug('Taskset_finish: ' + truncate(taskset.__str__()))
def taskset_event(self, taskset):
self._logger.debug('Taskset_event: ' + truncate(taskset.__str__()))
