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solution.py
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solution.py
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import sys
import cProfile
class output_result:
ROOT_UPDATE = 0
LEFT_TREE_UPDATE = 1
RIGHT_TREE_UPDATE = 2
def __init__(self):
self.root = []
self.ltree = []
self.rtree = []
self.bt_cnt = 0
self.obuf = ""
#for inserting the node
def __insert_node(self, node, tree_update):
if (tree_update == self.LEFT_TREE_UPDATE):
nl = []
nl.insert(0, node)
if (len(self.ltree) > 0):
t = self.ltree.pop(0)
nl.insert(1, t)
nl.insert(2, [])
else:
nl.insert(1, [])
nl.insert(2, [])
self.ltree.insert(0, nl)
elif (tree_update == self.RIGHT_TREE_UPDATE):
nl = []
nl.insert(0, node)
if (len(self.rtree) > 0):
t = self.rtree.pop(0)
nl.insert(1, [])
nl.insert(2, t)
else:
nl.insert(1, [])
nl.insert(2, [])
self.rtree.insert(0, nl)
else:
self.root.insert(0, node)
if (len(self.ltree) > 0):
self.root.insert(1, self.ltree[0])
else:
self.root.insert(1, [])
if (len(self.rtree) > 0):
self.root.insert(2, self.rtree[0])
else:
self.root.insert(2, [])
if len(node[1]) > 0 and node[1][0] != 0:
self.bt_cnt += 1
return
#for tree traversal
def __inorder_traversal(self, node):
if (len(node[1]) > 0):
self.__inorder_traversal(node[1])
if len(node[0][1]) > 0:
outputstr = ''.join(map(str, node[0][1]))
if (outputstr != "0"):
self.obuf += str(node[0][0]) + " " + outputstr + "\n"
if (len(node[2]) > 0):
self.__inorder_traversal(node[2])
return
def get_root(self):
return self.root
def get_tree_cnt(self):
return self.bt_cnt
def left_tree_add(self, node):
self.__insert_node(node, self.LEFT_TREE_UPDATE)
return
def right_tree_add(self, node):
self.__insert_node(node, self.RIGHT_TREE_UPDATE)
return
# add the root node
def root_add(self, node):
self.__insert_node(node, self.ROOT_UPDATE)
return
# print the output result
def print_output(self):
sys.stdout.write(str(self.bt_cnt) + "\n")
self.__inorder_traversal(self.root)
sys.stdout.write(self.obuf)
return
# each entry is stored as (asl, max-entries, mav-value)
ores = []
l = 0
r = 0
clv = 0
def create_ten_power_x_list(k):
if (k <= 1):
return [1, 0], 1
rl = [1]
r2p = 0
if (k > 1):
r2p = pow(2, k - 1)
rl = rl + [0]*r2p
return rl, r2p
# algo for a + b
def add_two_int_list(x, y):
# look for largest possible level
al = len(x)
bl = len(y)
if (bl == 0):
a = x[:]
elif (al == 0):
a = y[:]
else:
if (al < bl):
a = y[:]
minl = al
b = x
maxl = bl
elif (bl < al):
a = x[:]
maxl = al
b = y
minl = bl
else:
a = x[:]
b = y
maxl = al
minl = bl
carry = 0
i = 1
entries = 0
# a >= b as per this logic and result is also stored in a
while entries < minl:
sum_t = b[minl - i] + a[maxl - i] + carry
if (sum_t >= 10):
carry = 1
a[maxl - i] = sum_t - 10
else:
carry = 0
a[maxl - i] = sum_t
i += 1
entries += 1
# if carry > 0, then we need to do some more work
i = maxl - minl - 1
while carry > 0 and i >= 0:
sum_t = a[i] + carry
if (sum_t >= 10):
carry = 1
a[i] = sum_t - 10
else:
a[i] = sum_t
carry = 0
i -= 1
if (carry == 1):
a = [1] + a
if (a[0] == 0):
a.pop(0)
return a
# algo for a - b
def del_two_int_list(x, y):
al = len(x)
bl = len(y)
if al < bl:
return []
a = x[:]
b = y
if al == bl and a[0] < b[0]:
return []
a_i = al - 1
b_i = bl - 1
while (b_i >= 0):
# subtraction borrow logic
if (a[a_i] < b[b_i]):
a[a_i] = 10 + a[a_i]
i = 1
while a[a_i - i] == 0:
a[a_i - i] = 9
i += 1
a[a_i - i] -= 1
# subtract logic
a[a_i] = a[a_i] - b[b_i]
a_i -= 1
b_i -= 1
i = 0
while i < al:
if a[i] != 0:
break
i += 1
if i > 0:
a = a[i:]
# print "a: " + str(a)
return a
def compare_two_list_int(a, b):
a1 = len(a)
b1 = len(b)
if a1 > b1:
return 1
elif a1 < b1:
return -1
else:
i = 0
while (i < a1):
if (a[i] != b[i]):
if (a[i] > b[i]):
return 1
else:
return -1
i += 1
return 0
# a % b where b is the number of zeroes in 10
def divmod_10_list_int(x, b, mod_reqd):
c = []
a = x[:]
al = len(a)
if b >= len(a):
return a, [0]
if mod_reqd is True:
c = a[al - b:]
i = 0
while i < len(c):
if c[i] != 0:
break
i += 1
c = c[i:]
a = a[:al - b]
return c, a
def range_traverse():
global clv, l, r, ores
clv_me, clv_10s = create_ten_power_x_list(clv)
range_diff = del_two_int_list(r, l)
if compare_two_list_int(range_diff, clv_me) >= 0:
modl, divl = divmod_10_list_int(l, clv_10s, True)
del divl
lent = del_two_int_list(clv_me, modl)
if compare_two_list_int(lent, clv_me) == 0:
lent = [0]
rent, rentr = divmod_10_list_int(r, clv_10s, True)
tmpl = add_two_int_list(l, lent)
modl, l = divmod_10_list_int(tmpl, clv_10s, False)
del tmpl
del modl
modr, r = divmod_10_list_int(del_two_int_list(r, rent), clv_10s, False)
del modr
ores.left_tree_add((clv, lent))
ores.right_tree_add((clv, rent))
clv += 1
del range_diff
range_traverse()
else:
ent = range_diff
modent, divent = divmod_10_list_int(ent, clv_10s, True)
ores.root_add((clv, modent))
del range_diff
return
# @profile
def main():
global ores, l, r
ores = output_result()
l = list(map(int, (sys.stdin.readline()).strip()))
r = list(map(int, (sys.stdin.readline()).strip()))
l = del_two_int_list(l, [1])
range_traverse()
ores.print_output()
return
enable_profiling = 0
if __name__ == "__main__":
if (len(sys.argv) == 2):
if (sys.argv[1] == "profile"):
enable_profiling = 1
else:
print("usage: %s profile <optional>" % sys.argv[0])
exit(-1)
if (len(sys.argv) > 2):
print("usage: %s profile <optional>" % sys.argv[0])
exit(-1)
if (enable_profiling == 1):
cProfile.run('main()')
else:
main()
sys.exit(0)
# p.s. the problem is way too complex and intricated. Skip this problem if you have not much knowledge about the topic.