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Print the minimum number of operations required when Ringo can freely decide
how Snuke walks.
* * * | s299255092 | Accepted | p03132 | Input is given from Standard Input in the following format:
L
A_1
:
A_L | N = int(input())
A = []
for i in range(N):
A.append(int(input()))
dat = [A[i] for i in range(N)]
for i in range(1, N):
dat[i] += dat[i - 1]
evenf = [0] * N
evenf[0] = A[0] % 2
for i in range(1, N):
t = A[i] % 2
if A[i] == 0:
t = 2
evenf[i] = min(evenf[i - 1] + t, dat[i])
evenb = [0] * N
evenb[N - 1] = A[-1] % 2
for i in range(N - 2, -1, -1):
t = A[i] % 2
if A[i] == 0:
t = 2
if i != 0:
evenb[i] = min(evenb[i + 1] + t, dat[-1] - dat[i - 1])
else:
evenb[i] = min(evenb[i + 1] + t, dat[-1])
oddf = [0 for i in range(N)]
for i in range(1, N):
t = (1 + A[i]) % 2
oddf[i] = min(oddf[i - 1] + t, evenf[i])
ans = oddf[-1]
for i in range(N - 1):
ans = min(ans, evenb[i + 1] + oddf[i])
print(ans)
| Statement
Snuke stands on a number line. He has L ears, and he will walk along the line
continuously under the following conditions:
* He never visits a point with coordinate less than 0, or a point with coordinate greater than L.
* He starts walking at a point with integer coordinate, and also finishes walking at a point with integer coordinate.
* He only changes direction at a point with integer coordinate.
Each time when Snuke passes a point with coordinate i-0.5, where i is an
integer, he put a stone in his i-th ear.
After Snuke finishes walking, Ringo will repeat the following operations in
some order so that, for each i, Snuke's i-th ear contains A_i stones:
* Put a stone in one of Snuke's ears.
* Remove a stone from one of Snuke's ears.
Find the minimum number of operations required when Ringo can freely decide
how Snuke walks. | [{"input": "4\n 1\n 0\n 2\n 3", "output": "1\n \n\nAssume that Snuke walks as follows:\n\n * He starts walking at coordinate 3 and finishes walking at coordinate 4, visiting coordinates 3,4,3,2,3,4 in this order.\n\nThen, Snuke's four ears will contain 0,0,2,3 stones, respectively. Ringo can\nsatisfy the requirement by putting one stone in the first ear.\n\n* * *"}, {"input": "8\n 2\n 0\n 0\n 2\n 1\n 3\n 4\n 1", "output": "3\n \n\n* * *"}, {"input": "7\n 314159265\n 358979323\n 846264338\n 327950288\n 419716939\n 937510582\n 0", "output": "1"}] |
Print the minimum number of operations required when Ringo can freely decide
how Snuke walks.
* * * | s660148785 | Accepted | p03132 | Input is given from Standard Input in the following format:
L
A_1
:
A_L | import sys
def calc(itr):
dp = [0]
turn, no_turn, no_visit = 0, 0, 0
for a in itr:
b = a % 2
new_turn = min(turn, no_visit) + (2 if a == 0 else b)
new_no_turn = min(turn, no_turn, no_visit) + (b ^ 1)
new_no_visit = no_visit + a
dp.append(min(new_turn, new_no_turn, new_no_visit))
turn, no_turn, no_visit = new_turn, new_no_turn, new_no_visit
return dp
l = int(input())
aaa = list(map(int, sys.stdin))
dp_f = calc(aaa)
dp_b = calc(reversed(aaa))
dp_b.reverse()
print(min(map(sum, zip(dp_f, dp_b))))
| Statement
Snuke stands on a number line. He has L ears, and he will walk along the line
continuously under the following conditions:
* He never visits a point with coordinate less than 0, or a point with coordinate greater than L.
* He starts walking at a point with integer coordinate, and also finishes walking at a point with integer coordinate.
* He only changes direction at a point with integer coordinate.
Each time when Snuke passes a point with coordinate i-0.5, where i is an
integer, he put a stone in his i-th ear.
After Snuke finishes walking, Ringo will repeat the following operations in
some order so that, for each i, Snuke's i-th ear contains A_i stones:
* Put a stone in one of Snuke's ears.
* Remove a stone from one of Snuke's ears.
Find the minimum number of operations required when Ringo can freely decide
how Snuke walks. | [{"input": "4\n 1\n 0\n 2\n 3", "output": "1\n \n\nAssume that Snuke walks as follows:\n\n * He starts walking at coordinate 3 and finishes walking at coordinate 4, visiting coordinates 3,4,3,2,3,4 in this order.\n\nThen, Snuke's four ears will contain 0,0,2,3 stones, respectively. Ringo can\nsatisfy the requirement by putting one stone in the first ear.\n\n* * *"}, {"input": "8\n 2\n 0\n 0\n 2\n 1\n 3\n 4\n 1", "output": "3\n \n\n* * *"}, {"input": "7\n 314159265\n 358979323\n 846264338\n 327950288\n 419716939\n 937510582\n 0", "output": "1"}] |
Print the minimum number of operations required when Ringo can freely decide
how Snuke walks.
* * * | s277430730 | Wrong Answer | p03132 | Input is given from Standard Input in the following format:
L
A_1
:
A_L | def calc(A):
tmp = [not (a % 2) for a in A]
tl = 0
max_tl = 0
for tf in tmp:
if tf:
tl += 1
else:
max_tl = max(max_tl, tl)
tl = 0
return sum(tmp), max_tl
L = int(input())
A = [0 for i in range(L)]
ans = 0
max_tl = 0
zs, ze, zl = 0, 0, 0
for i in range(L):
Ai = int(input())
A[i] = Ai
if Ai == 0:
A[i] = 1
if zl == 0:
zs = i
zl += 1
continue
elif zl != 0:
sub_sum = sum(A[ze:zs])
if sub_sum > zl:
tmp_sum, tl = calc(A[ze:zs])
max_tl = max(max_tl, tl)
ans += tmp_sum
else:
ans += zl
ze = i
zl = 0
tmp_sum, tl = calc(A[ze:])
max_tl = max(max_tl, tl)
ans += tmp_sum
print(ans - max_tl)
| Statement
Snuke stands on a number line. He has L ears, and he will walk along the line
continuously under the following conditions:
* He never visits a point with coordinate less than 0, or a point with coordinate greater than L.
* He starts walking at a point with integer coordinate, and also finishes walking at a point with integer coordinate.
* He only changes direction at a point with integer coordinate.
Each time when Snuke passes a point with coordinate i-0.5, where i is an
integer, he put a stone in his i-th ear.
After Snuke finishes walking, Ringo will repeat the following operations in
some order so that, for each i, Snuke's i-th ear contains A_i stones:
* Put a stone in one of Snuke's ears.
* Remove a stone from one of Snuke's ears.
Find the minimum number of operations required when Ringo can freely decide
how Snuke walks. | [{"input": "4\n 1\n 0\n 2\n 3", "output": "1\n \n\nAssume that Snuke walks as follows:\n\n * He starts walking at coordinate 3 and finishes walking at coordinate 4, visiting coordinates 3,4,3,2,3,4 in this order.\n\nThen, Snuke's four ears will contain 0,0,2,3 stones, respectively. Ringo can\nsatisfy the requirement by putting one stone in the first ear.\n\n* * *"}, {"input": "8\n 2\n 0\n 0\n 2\n 1\n 3\n 4\n 1", "output": "3\n \n\n* * *"}, {"input": "7\n 314159265\n 358979323\n 846264338\n 327950288\n 419716939\n 937510582\n 0", "output": "1"}] |
Print the minimum number of operations required when Ringo can freely decide
how Snuke walks.
* * * | s261030407 | Wrong Answer | p03132 | Input is given from Standard Input in the following format:
L
A_1
:
A_L | n = int(input())
A = [int(input()) for i in range(n)]
s = 0
Z = []
R = []
z = 0
r = 0
for a in A:
if a == 0:
z += 1
r += a
Z.append(z)
R.append(r)
for i in range(n - 1, -1, -1):
if Z[i] >= R[i]:
s += sum(A[: i + 1])
A = A[i + 1 :]
break
if A == []:
print(s)
exit()
Z = []
R = []
z = 0
r = 0
for a in A[::-1]:
if a == 0:
z += 1
r += a
Z.append(z)
R.append(r)
Z = Z[::-1]
R = R[::-1]
for i in range(len(A)):
if Z[i] >= R[i]:
s += sum(A[i:])
A = A[:i]
break
if A == []:
print(s)
exit()
for i in range(len(A)):
if A[i] == 0:
s += 1
A[i] = 1
s0 = s
O = []
E = []
o = 0
e = 0
for a in A:
if a % 2 == 0:
e += 1
else:
o += 1
E.append(e)
O.append(o)
l = 0
f = 0
for i in range(len(A) - 1, -1, -1):
if E[i] > O[i] and f == 1:
s += O[i]
A = A[i + 1 :]
break
if A[i] == 1:
f = 1
O = []
E = []
o = 0
e = 0
for a in A[::-1]:
if a % 2 == 0:
e += 1
else:
o += 1
E.append(e)
O.append(o)
l = 0
f = 0
E = E[::-1]
O = O[::-1]
for i in range(len(A)):
if E[i] > O[i]:
s += O[i]
A = A[i + 1 :]
break
O = []
E = []
o = 0
e = 0
for a in A[::-1]:
if a % 2 == 0:
e += 1
else:
o += 1
E.append(e)
O.append(o)
l = 0
f = 0
E = E[::-1]
O = O[::-1]
for i in range(len(A)):
if E[i] > O[i]:
s0 += O[i]
A = A[i + 1 :]
break
O = []
E = []
o = 0
e = 0
for a in A:
if a % 2 == 0:
e += 1
else:
o += 1
E.append(e)
O.append(o)
l = 0
f = 0
for i in range(len(A) - 1, -1, -1):
if E[i] > O[i]:
s0 += O[i]
A = A[i + 1 :]
break
print(min(s, s0))
| Statement
Snuke stands on a number line. He has L ears, and he will walk along the line
continuously under the following conditions:
* He never visits a point with coordinate less than 0, or a point with coordinate greater than L.
* He starts walking at a point with integer coordinate, and also finishes walking at a point with integer coordinate.
* He only changes direction at a point with integer coordinate.
Each time when Snuke passes a point with coordinate i-0.5, where i is an
integer, he put a stone in his i-th ear.
After Snuke finishes walking, Ringo will repeat the following operations in
some order so that, for each i, Snuke's i-th ear contains A_i stones:
* Put a stone in one of Snuke's ears.
* Remove a stone from one of Snuke's ears.
Find the minimum number of operations required when Ringo can freely decide
how Snuke walks. | [{"input": "4\n 1\n 0\n 2\n 3", "output": "1\n \n\nAssume that Snuke walks as follows:\n\n * He starts walking at coordinate 3 and finishes walking at coordinate 4, visiting coordinates 3,4,3,2,3,4 in this order.\n\nThen, Snuke's four ears will contain 0,0,2,3 stones, respectively. Ringo can\nsatisfy the requirement by putting one stone in the first ear.\n\n* * *"}, {"input": "8\n 2\n 0\n 0\n 2\n 1\n 3\n 4\n 1", "output": "3\n \n\n* * *"}, {"input": "7\n 314159265\n 358979323\n 846264338\n 327950288\n 419716939\n 937510582\n 0", "output": "1"}] |
Print the minimum number of operations required when Ringo can freely decide
how Snuke walks.
* * * | s175335728 | Accepted | p03132 | Input is given from Standard Input in the following format:
L
A_1
:
A_L | # coding: utf-8
# Your code here!
# k,a,b = [int(i) for i in input().split()]
l = int(input())
a = [int(input()) for i in [0] * l]
asum = [0] * (l + 1)
for i in range(1, l + 1):
asum[i] = asum[i - 1] + a[i - 1]
reven = [0] * (l + 1)
leven = [0] * (l + 1)
rodd = [0] * (l + 1)
lodd = [0] * (l + 1)
for i in range(1, l + 1):
if a[i - 1] != 0:
leven[i] = leven[i - 1] + a[i - 1] % 2
else:
leven[i] = min(2 + leven[i - 1], asum[i])
for i in range(l - 1, -1, -1):
if a[i] != 0:
reven[i] = reven[i + 1] + a[i] % 2
else:
reven[i] = min(2 + reven[i + 1], asum[l] - asum[i])
for i in range(1, l + 1):
lodd[i] = min(leven[i], lodd[i - 1] + (a[i - 1] + 1) % 2, asum[i])
for i in range(l - 1, -1, -1):
rodd[i] = min(reven[i], rodd[i + 1] + (a[i] + 1) % 2, asum[l] - asum[i])
# print(asum)
# print(reven)
# print(leven)
# print(rodd)
# print(lodd)
ans = 5 * (l + 2)
for i in range(l + 1):
ans = min(ans, leven[i] + rodd[i], lodd[i] + reven[i])
print(ans)
| Statement
Snuke stands on a number line. He has L ears, and he will walk along the line
continuously under the following conditions:
* He never visits a point with coordinate less than 0, or a point with coordinate greater than L.
* He starts walking at a point with integer coordinate, and also finishes walking at a point with integer coordinate.
* He only changes direction at a point with integer coordinate.
Each time when Snuke passes a point with coordinate i-0.5, where i is an
integer, he put a stone in his i-th ear.
After Snuke finishes walking, Ringo will repeat the following operations in
some order so that, for each i, Snuke's i-th ear contains A_i stones:
* Put a stone in one of Snuke's ears.
* Remove a stone from one of Snuke's ears.
Find the minimum number of operations required when Ringo can freely decide
how Snuke walks. | [{"input": "4\n 1\n 0\n 2\n 3", "output": "1\n \n\nAssume that Snuke walks as follows:\n\n * He starts walking at coordinate 3 and finishes walking at coordinate 4, visiting coordinates 3,4,3,2,3,4 in this order.\n\nThen, Snuke's four ears will contain 0,0,2,3 stones, respectively. Ringo can\nsatisfy the requirement by putting one stone in the first ear.\n\n* * *"}, {"input": "8\n 2\n 0\n 0\n 2\n 1\n 3\n 4\n 1", "output": "3\n \n\n* * *"}, {"input": "7\n 314159265\n 358979323\n 846264338\n 327950288\n 419716939\n 937510582\n 0", "output": "1"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s797726412 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | N = int(input())
monsters = list(map(int, input().split()))
powers = list(map(int, input().split()))
# dp[i] = i番目の街のモンスターを最も多く倒せる数
dp = [0 for _ in range(N + 1)]
# 初期条件
# 勇者パワーの方が少ない場合その数しか倒せない
# モンスター数の方が少ない場合もその数しか倒せない
# print(f"powers: {powers}")
dp[N] = min(monsters[N], powers[N - 1])
# 勇者の火力を減らしておく
powers[N - 1] -= dp[N]
# Nから-1ずつ下がって0まで処理する
for i in range(N - 1, 0, -1):
# print(f"powers: {powers}")
# i番目の倒せる最大数を求める
# i番目の勇者がi+1番目のモンスターを倒して残った火力 + i-1番目の勇者の火力と
# i番目のモンスター数の内、少ない方が倒せる最大数になる
dp[i] = min(powers[i] + powers[i - 1], monsters[i])
# i-1番目の勇者の火力を減らしておく
# ただしi番目の勇者で十分倒せる火力の場合何も減らさない
powers[i - 1] -= max(dp[i] - powers[i], 0)
# print(f"powers: {powers}")
# 0番目の勇者の倒せる最大数を求める
dp[0] = min(powers[0], monsters[0])
print(sum(dp))
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s436572793 | Wrong Answer | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | N = int(input())
inputsA = input().split()
inputsB = input().split()
A = [int(n) for n in inputsA]
B = [int(n) for n in inputsB]
enemy = 0
attack = 0
dif = 0
enemy += A[0]
temp = A[0] - B[0]
if temp > 0:
dif += temp
for i in range(1, N):
enemy += A[i]
attack += B[i - 1]
temp = A[i] - B[i - 1] - B[i]
if temp > 0:
dif += temp
enemy += A[N]
attack += B[N - 1]
temp = A[N] - B[N - 1]
if temp > 0:
dif += temp
result = enemy - dif
if result > attack:
result = attack
print(result)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s635053537 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | n = int(input())
aaa = list(map(int, input().split()))
sa = sum(aaa)
bbb = list(map(int, input().split()))
for i, b in enumerate(bbb):
c = min(aaa[i], b)
aaa[i] -= c
aaa[i + 1] -= min(aaa[i + 1], b - c)
print(sa - sum(aaa))
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s906442978 | Wrong Answer | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | # -*- coding: utf-8 -*-
N = int(input())
A = list(map(int, input().split()))
B = list(map(int, input().split()))
reverse_A = list(reversed(A))
reverse_B = list(reversed(B))
sum = 0
if (B[N - 1] - A[N]) >= (B[0] - A[0]):
for n in range(len(reverse_A)):
if n == 0:
if (reverse_B[n] - reverse_A[n]) >= 0:
sum += reverse_A[n]
temp = reverse_B[n] - reverse_A[n]
else:
sum += reverse_B[n]
temp = 0
elif n >= 1 and n <= (N - 1):
if (temp + reverse_B[n] - reverse_A[n]) >= 0:
sum += reverse_A[n]
if (temp - reverse_A[n]) >= 0:
temp = reverse_B[n]
else:
temp = temp + reverse_B[n] - reverse_A[n]
else:
sum += reverse_B[n]
temp = 0
elif n == N:
if (temp - reverse_A[n]) >= 0:
sum += reverse_A[n]
else:
sum += temp
else:
for n in range(len(A)):
if n == 0:
if (B[n] - A[n]) >= 0:
sum += A[n]
temp = B[n] - A[n]
else:
sum += B[n]
temp = 0
elif n >= 1 and n <= (N - 1):
if (temp + B[n] - A[n]) >= 0:
sum += A[n]
if (temp - A[n]) >= 0:
temp = B[n]
else:
temp = temp + B[n] - A[n]
else:
sum += B[n]
temp = 0
elif n == N:
if (temp - A[n]) >= 0:
sum += A[n]
else:
sum += temp
print(sum)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s797141728 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | sentence = input()
N = int(sentence)
sentence = input()
a_str = sentence.split()
a_list = [int(a) for a in a_str]
sentence = input()
b_str = sentence.split()
b_list = [int(b) for b in b_str]
a_list.reverse()
b_list.reverse()
remain = a_list.pop(0)
total_number = 0
for i, b in enumerate(b_list):
if remain >= b:
total_number += b
remain = a_list[i]
else:
total_number += remain
b_remain = b - remain
monster_a = a_list[i]
if monster_a >= b_remain:
total_number += b_remain
remain = monster_a - b_remain
else:
total_number += monster_a
remain = 0
print(total_number)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s268575278 | Wrong Answer | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | f = lambda: map(int, input().split())
input()
p, *A = f()
B = f()
s = 0
for a, b in zip(A, B):
t = min(b, a + p)
p = a - max(0, t - b)
s += t
print(s)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s527836720 | Wrong Answer | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | import glob
# 問題ごとのディレクトリのトップからの相対パス
REL_PATH = "ABC\\135\\C"
# テスト用ファイル置き場のトップ
TOP_PATH = "C:\\AtCoder"
class Common:
problem = []
index = 0
def __init__(self, rel_path):
self.rel_path = rel_path
def initialize(self, path):
file = open(path)
self.problem = file.readlines()
self.index = 0
return
def input_data(self):
try:
IS_TEST
self.index += 1
return self.problem[self.index - 1]
except NameError:
return input()
def resolve(self):
pass
def exec_resolve(self):
try:
IS_TEST
for path in glob.glob(TOP_PATH + "\\" + self.rel_path + "/*.txt"):
print("Test: " + path)
self.initialize(path)
self.resolve()
print("\n\n")
except NameError:
self.resolve()
class C(Common):
def resolve(self):
N = int(self.input_data())
monster = [int(i) for i in self.input_data().split()]
saver = [int(i) for i in self.input_data().split()]
result = 0
remaining = 0
for i in range(N):
if saver[i] + remaining > monster[i]:
result += monster[i]
remaining = saver[i] + remaining - monster[i]
else:
result += saver[i] + remaining
remaining = 0
if remaining > monster[N]:
result += monster[N]
else:
result += remaining
print(str(result))
solver = C(REL_PATH)
solver.exec_resolve()
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s820840800 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | LARGE = 10**9 + 7
def solve_a(test=False, a=2, b=16):
if not test:
a, b = map(int, input().split())
if (b - a) % 2 == 0:
print((a + b) // 2)
else:
print("IMPOSSIBLE")
def solve_b(test=False, n=5, p_list=[5, 2, 3, 4, 1]):
if not test:
n = int(input())
p_list = list(map(int, input().split()))
r = 0
for i in range(n):
if p_list[i] != i + 1:
r += 1
if r == 0 or r == 2:
print("YES")
else:
print("NO")
def solve_c(test=False, n=2, a_list=[3, 5, 2], b_list=[4, 5]):
if not test:
n = int(input())
a_list = list(map(int, input().split()))
b_list = list(map(int, input().split()))
res = 0
for i in range(n):
if b_list[i] <= a_list[i]:
res += b_list[i]
a_list[i] -= b_list[i]
elif b_list[i] < a_list[i] + a_list[i + 1]:
res += b_list[i]
a_list[i + 1] -= b_list[i] - a_list[i]
a_list[i] = 0
else:
res += a_list[i] + a_list[i + 1]
a_list[i] = 0
a_list[i + 1] = 0
print(res)
def solve_d(test=False, s="??2??5"):
if not test:
s = input()
l = len(s)
res_list_new = [0] * 13
res_list_old = [0] * 13
zero_mod = int(s.replace("?", "0")) % 13
res_list_new[zero_mod] += 1
for i in range(1, l + 1):
if s[-i] == "?":
for k in range(13):
res_list_old[k] = res_list_new[k] % LARGE
base_mod = pow(10, i - 1, 13)
for j in range(1, 10):
for k in range(13):
res_list_new[(k + base_mod * j) % 13] += res_list_old[k]
print(res_list_new[5] % LARGE)
# solve_a(test=True, a=2, b=16)
# solve_a(test=True, a=0, b=3)
# solve_a(test=True, a=998244353, b=99824435)
# solve_b(test=True, n=5, p_list=[5, 2, 3, 4, 1])
# solve_b(test=True, n=5, p_list=[2, 4, 3, 5, 1])
# solve_b(test=True, n=7, p_list=[1, 2, 3, 4, 5, 6, 7])
# solve_c(test=True, n=2, a_list=[3, 5, 2], b_list=[4, 5])
# solve_c(test=True, n=3, a_list=[5, 6, 3, 8], b_list=[5, 100, 8])
# solve_c(test=True, n=2, a_list=[100, 1, 1], b_list=[1, 100])
# solve_d(test=True, s='??2??5')
# solve_d(test=True, s='?44')
# solve_d(test=True, s='7?4')
# solve_d(test=True, s='?6?42???8??2??06243????9??3???7258??5??7???????774????4?1??17???9?5?70???76???')
solve_c()
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s490736587 | Wrong Answer | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | i1 = int(input())
i2 = input().split(" ")
i3 = input().split(" ")
w = -1
s = 0
for i in range(i1):
ii2 = int(i2[i])
ii3 = int(i3[i])
# print(ii2)
# print(ii3)
if ii2 > ii3:
# 引ききれた場合
s += ii3
else:
s += ii2
w = ii3 - ii2
iii2 = int(i2[i + 1])
if iii2 > w:
s += w
w = iii2 - w
else:
s += iii2
w = 0
print(s)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s707840944 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | from collections import deque
N = int(input())
Monsters = deque(map(int, input().split()))
Fighters = deque(map(int, input().split()))
Knockouts = 0
prev_ftr = 0
while len(Monsters) > 0:
mon = Monsters.popleft()
ko1 = min(mon, prev_ftr)
# print(mon, prev_ftr, ko1)
Knockouts += ko1
mon -= ko1
if len(Fighters) > 0:
ftr = Fighters.popleft()
ko2 = min(mon, ftr)
# print(mon, ftr, ko2)
Knockouts += ko2
mon -= ko2
prev_ftr = ftr - ko2
print(Knockouts)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s821048453 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | n = int(input())
a = [0] * (n + 1)
b = [0] * n
a[:] = map(int, input().split())
b[:] = map(int, input().split())
r = sum(a)
minab = min(a[0], b[0])
a[0] -= minab
b[0] -= minab
for ii in range(n):
minab = min(a[ii + 1], b[ii])
a[ii + 1] -= minab
b[ii] -= minab
if ii + 1 < n:
minab = min(a[ii + 1], b[ii + 1])
a[ii + 1] -= minab
b[ii + 1] -= minab
print(r - sum(a))
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s790100707 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | N = int(input())
mon = [int(x) for x in input().split()]
her = [int(x) for x in input().split()]
n = 0
for i in range(len(her)):
z = min(mon[i], her[i])
mon[i] -= z
her[i] -= z
n += z
z = min(mon[i + 1], her[i])
mon[i + 1] -= z
her[i] -= z
n += z
print(n)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s492165013 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | n = int(input())
a = list(map(int, input().split())) # 初期のモンスターの数
b = list(map(int, input().split())) # 各勇者が倒せるモンスターの数
num = 0
for i in range(n):
# 倒したモンスターの数をnumに追加
num += min(a[i], b[i])
if b[i] - a[i] > 0: # モンスターが残っていないとき
# 隣町の勇者が倒せるモンスターの数か,隣町のモンスター全てか.
num += min(b[i] - a[i], a[i + 1])
# 隣町のモンスター数は残っているか,全滅しているか.
a[i + 1] = max(a[i + 1] - (b[i] - a[i]), 0)
print(num)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s918494435 | Wrong Answer | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | S = int(input())
alist = input().split()
blist = input().split()
for i, a in enumerate(alist):
alist[i] = int(a)
for i, a in enumerate(blist):
blist[i] = int(a)
alist.sort()
blist.sort()
tlist = []
for i, a in enumerate(blist):
for b, d in enumerate(alist):
if d <= a:
tlist.append(alist.pop(b))
print(sum(tlist))
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print the maximum total number of monsters the heroes can defeat.
* * * | s485842292 | Accepted | p02959 | Input is given from Standard Input in the following format:
N
A_1 A_2 ... A_{N+1}
B_1 B_2 ... B_N | n = int(input())
a = list(map(int, input().split()))
asum = sum(a)
b = list(map(int, input().split()))
for i in range(n):
if (
a[n - i] <= b[n - i - 1]
): # 勇者の次の街にいるモンスターが勇者が倒せる数より少ない場合
b[n - i - 1] -= a[n - i]
a[n - i] = 0
if (
a[n - i - 1] <= b[n - i - 1]
): # 勇者の街にいるモンスターが勇者が倒せる数ののこりより少ない場合
b[n - i - 1] -= a[n - i - 1]
a[n - i - 1] = 0
else:
a[n - i - 1] -= b[n - i - 1]
b[n - i - 1] = 0
else:
a[n - i] -= b[n - i - 1]
b[n - i - 1] = 0
answer = asum - sum(a)
print(answer)
| Statement
There are N+1 towns. The i-th town is being attacked by A_i monsters.
We have N heroes. The i-th hero can defeat monsters attacking the i-th or
(i+1)-th town, for a total of at most B_i monsters.
What is the maximum total number of monsters the heroes can cooperate to
defeat? | [{"input": "2\n 3 5 2\n 4 5", "output": "9\n \n\nIf the heroes choose the monsters to defeat as follows, they can defeat nine\nmonsters in total, which is the maximum result.\n\n * The first hero defeats two monsters attacking the first town and two monsters attacking the second town.\n * The second hero defeats three monsters attacking the second town and two monsters attacking the third town.\n\n* * *"}, {"input": "3\n 5 6 3 8\n 5 100 8", "output": "22\n \n\n* * *"}, {"input": "2\n 100 1 1\n 1 100", "output": "3"}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s591158791 | Accepted | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | #!/usr/bin/env python3
def main() -> None:
N = ri()
a = rmi()
assert len(a) == N
result = []
all_xor = 0
for item in a:
all_xor ^= item
for item in a:
result.append(item ^ all_xor)
w(" ".join(map(str, result)))
def r() -> str:
return input().strip()
def ri() -> int:
return int(r())
def rmi(delim: str = " ") -> tuple:
return tuple(map(int, input().split(delim)))
def w(data) -> None:
print(data)
def wm(*data, delim: str = " ") -> None:
print(delim.join(map(str, data)))
if __name__ == "__main__":
import sys
sys.setrecursionlimit(10**9)
main()
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s871267756 | Wrong Answer | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | input()
print(input())
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s353272350 | Accepted | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | n = int(input())
x = [int(x) for x in input().split()]
s = x[0]
for i in range(1, len(x)):
s = s ^ x[i]
z = []
for i in range(len(x)):
z.append(s ^ x[i])
print(*z)
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s758961156 | Accepted | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | N, *D = map(int, open(0).read().split())
ALL = 0
for d in D:
ALL ^= d
D = map(lambda x: x ^ ALL, D)
print(*D, sep=" ")
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s503793018 | Accepted | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | N = int(input())
A = list(map(int, input().split()))
maxA = max(A)
maxl = len(bin(maxA)[2:])
binary_c = [0 for _ in range(maxl)]
A_binary = [bin(a)[2:].zfill(maxl) for a in A]
for a in A_binary:
for i, n in enumerate(a):
if n == "1":
binary_c[i] += 1
is_inv = []
for bc in binary_c:
if bc % 2 == 0:
is_inv.append(False)
else:
is_inv.append(True)
for a in A_binary:
l = []
for i, n in enumerate(a):
if is_inv[i]:
if n == "0":
l.append("1")
else:
l.append("0")
else:
l.append(n)
print(int("".join(l), 2))
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s153319168 | Accepted | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | n = int(input())
l = list(map(int, input().split()))
ret = [0] * n
now = 1
for i in range(max(l).bit_length()):
z = 0
for j in range(n):
if l[j] % 2:
z += 1
for j in range(n):
ret[j] += (l[j] % 2 + z) % 2 * now
l[j] //= 2
now *= 2
print(*ret, sep=" ")
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s823951384 | Wrong Answer | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | n = int(input())
a = list(map(int, input().split()))
b = [[] for _ in range(n)]
c = [0] * 30
d = []
for i in range(n):
m = a[i]
while m > 0:
b[i].append(m % 2)
m //= 2
for i in range(n):
for j in range(len(b[i])):
c[j] += b[i][j]
for i in range(30):
c[i] = c[i] % 2
for i in range(n):
e = 0
for j in range(len(b[i])):
if b[i][j] + c[j] == 1:
e += 2**j
d.append(e)
print(*d)
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s853503108 | Wrong Answer | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | N = int(input())
a = list(map(int, input().split()))
b = ["" for i in range(N)]
def int_to_2(X):
r = ""
while X > 0:
r = r + str(X % 2)
X = int((X - X % 2) / 2)
return r
for i in range(N):
b[i] = int_to_2(a[i])
def xor(aa, bb):
rr = ""
if len(bb) > len(aa):
cc = bb
bb = aa
aa = cc
for i in range(len(aa) - len(bb)):
bb = bb + "0"
for i in range(len(aa)):
if aa[i] != bb[i]:
rr = rr + "1"
else:
rr = rr + "0"
return rr
def bi_to_int(rr):
r = 0
for i in range(len(rr)):
r = r + (2**i) * int(rr[i])
return r
anss = ["" for i in range(N)]
for i in range(N - 1):
anss[0] = xor(anss[0], b[i + 1])
for i in range(N - 1):
anss[i + 1] = xor(anss[i], xor(b[i], b[i + 1]))
writeout = ""
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s903732237 | Wrong Answer | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | N = int(input())
a = list(map(int, input().split()))
bina = []
for k in range(N):
bina.append(str(bin(a[k]))[2:])
# print(bina)
A = 0
b = 1
longest = len(bina[a.index(max(a))])
for k in range(1, longest + 1):
foo = 0
for j in range(N):
if len(bina[j]) >= k:
foo += int(bina[j][-k])
foo = foo % 2
foo = foo * b
A += foo
b = b * 2
A = str(bin(A))[2:]
if longest > len(A):
A = "0" * (longest - len(A)) + A
# print(A)
ans = [0 for k in range(N)]
# binans = []
for k in range(N):
b = 1
for j in range(1, len(bina[k]) + 1):
if bina[k][-j] != A[-j]:
ans[k] += b
b = b * 2
# binans.append(bin(ans[k])[2:])
ans[k] = str(ans[k])
# print(binans)
print(" ".join(ans))
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s315959655 | Accepted | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | # -*- coding: utf-8 -*-
def cal_xor(xor_list):
ans = None
for xi in xor_list:
if ans is not None:
ans = ans ^ xi
else:
ans = xi
return ans
(N,) = map(int, input().split())
a = list(map(int, input().split()))
ans_str = ""
if N == 2:
print("{} {}".format(a[1], a[0]))
else:
xors = []
for i in range(N // 2):
xors.append(a[2 * i] ^ a[2 * i + 1])
sum_xor = cal_xor(xors)
for i, ai in enumerate(a):
tmp_xor = sum_xor ^ xors[i // 2]
if i % 2 == 0:
ind = i + 1
else:
ind = i - 1
ans = tmp_xor ^ a[ind]
ans_str += str(ans) + " "
print(ans_str[:-1])
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s815846036 | Wrong Answer | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | N = input()
strs = input().split(" ")
nums = list(map(int,strs ))
all = []
ma = max(nums)
ma_l = len(format(ma,"b"))
all_nums = [0] * ma_l
for num in nums:
bins = format(num,"b")
bins = bins[::-1]
for i,c in enumerate(bins):
if c == "1":
all_nums[i] += 1
all_nums.reverse()
anss = []
for num in nums:
s = num
bins = format(num,"b")
bins = bins[::-1]
ans = 0
jo = 1
for i in range(ma_l):
if len(bins) - 1 < i:
hoge = 0
else:
c = bins[i]
hoge = int(c )
if (all_nums[i] - hoge) % 2 == 1:
ans += jo
jo *= 2
anss.append(ans)
print(*anss)
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print a line containing N integers separated with space.
The i-th of the integers from the left should represent the integer written on
the scarf of Snuke Cat i.
If there are multiple possible solutions, you may print any of them.
* * * | s906683066 | Wrong Answer | p02631 | Input is given from Standard Input in the following format:
N
a_1 a_2 \ldots a_N | n = int(input())
a = list(map(int, input().split()))
nl = []
for i in a:
s = str(format(i, "b"))
for c in range(len(s)):
if len(nl) > c:
if s[len(s) - (c + 1)] == "1":
nl[c] += 1
else:
if s[len(s) - (c + 1)] == "1":
nl.append(1)
else:
nl.append(0)
ansl = []
for i in a:
s = str(format(i, "b"))
ans = nl.copy()
for c in range(len(s)):
ans[len(s) - (c + 1)] -= int(s[c])
if ans[len(s) - (c + 1)] % 2 == 0:
ans[len(s) - (c + 1)] = 0
else:
ans[len(s) - (c + 1)] = 1
p = 0
for i in range(len(s)):
p += ans[i] * 2**i
ansl.append(p)
for i in range(len(ansl) - 1):
print(ansl[i], end=" ")
print(ansl[len(ansl) - 1])
| Statement
There are N Snuke Cats numbered 1, 2, \ldots, N, where N is **even**.
Each Snuke Cat wears a red scarf, on which his favorite non-negative integer
is written.
Recently, they learned the operation called xor (exclusive OR).
What is xor?
For n non-negative integers x_1, x_2, \ldots, x_n, their xor,
x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is defined as
follows:
* When x_1~\textrm{xor}~x_2~\textrm{xor}~\ldots~\textrm{xor}~x_n is written in base two, the digit in the 2^k's place (k \geq 0) is 1 if the number of integers among x_1, x_2, \ldots, x_n whose binary representations have 1 in the 2^k's place is odd, and 0 if that count is even.
For example, 3~\textrm{xor}~5 = 6.
They wanted to use this operation quickly, so each of them calculated the xor
of the integers written on their scarfs except his scarf.
We know that the xor calculated by Snuke Cat i, that is, the xor of the
integers written on the scarfs except the scarf of Snuke Cat i is a_i. Using
this information, restore the integer written on the scarf of each Snuke Cat. | [{"input": "4\n 20 11 9 24", "output": "26 5 7 22\n \n\n * 5~\\textrm{xor}~7~\\textrm{xor}~22 = 20\n * 26~\\textrm{xor}~7~\\textrm{xor}~22 = 11\n * 26~\\textrm{xor}~5~\\textrm{xor}~22 = 9\n * 26~\\textrm{xor}~5~\\textrm{xor}~7 = 24\n\nThus, this output is consistent with the given information."}] |
Print the shortest time needed to produce at least N cookies not yet eaten.
* * * | s057181625 | Wrong Answer | p03923 | The input is given from Standard Input in the following format:
N A | n, a = map(int, input().split())
ans = 10**18
for k in range(2):
l = 0
r = n
while r - l != 1:
m = (r + l) // 2
if m ** (k + 1) >= n:
r = m
else:
l = m
for m in range(k + 2):
if (l**m) * (r ** ((k + 1) - m)) >= n:
ans = min(ans, k * a + l * m + r * ((k + 1) - m))
print(ans)
| Statement
Rng is baking cookies.
Initially, he can bake one cookie per second.
He can also eat the cookies baked by himself. When there are x cookies not yet
eaten, he can choose to eat all those cookies. After he finishes eating those
cookies, the number of cookies he can bake per second becomes x. Note that a
cookie always needs to be baked for 1 second, that is, he cannot bake a cookie
in 1/x seconds when x > 1. When he choose to eat the cookies, he must eat all
of them; he cannot choose to eat only part of them. It takes him A seconds to
eat the cookies regardless of how many, during which no cookies can be baked.
He wants to give N cookies to Grandma. Find the shortest time needed to
produce at least N cookies not yet eaten. | [{"input": "8 1", "output": "7\n \n\nIt is possible to produce 8 cookies in 7 seconds, as follows:\n\n * After 1 second: 1 cookie is done.\n * After 2 seconds: 1 more cookie is done, totaling 2. Now, Rng starts eating those 2 cookies.\n * After 3 seconds: He finishes eating the cookies, and he can now bake 2 cookies per second.\n * After 4 seconds: 2 cookies are done.\n * After 5 seconds: 2 more cookies are done, totaling 4.\n * After 6 seconds: 2 more cookies are done, totaling 6.\n * After 7 seconds: 2 more cookies are done, totaling 8.\n\n* * *"}, {"input": "1000000000000 1000000000000", "output": "1000000000000"}] |
Print the shortest time needed to produce at least N cookies not yet eaten.
* * * | s978216334 | Runtime Error | p03923 | The input is given from Standard Input in the following format:
N A | n, a = map(int, input().split())
costs = [10**18] * (n + 1)
costs[1] = 0
times = [0] * (n + 1)
for i in range(1, n + 1):
times[i] = costs[i] + (n + i - 1) // i
for j in range(2, n // i + 1):
costs[i * j] = min(costs[i * j], costs[i] + j + a)
print(min(times[1:]))
| Statement
Rng is baking cookies.
Initially, he can bake one cookie per second.
He can also eat the cookies baked by himself. When there are x cookies not yet
eaten, he can choose to eat all those cookies. After he finishes eating those
cookies, the number of cookies he can bake per second becomes x. Note that a
cookie always needs to be baked for 1 second, that is, he cannot bake a cookie
in 1/x seconds when x > 1. When he choose to eat the cookies, he must eat all
of them; he cannot choose to eat only part of them. It takes him A seconds to
eat the cookies regardless of how many, during which no cookies can be baked.
He wants to give N cookies to Grandma. Find the shortest time needed to
produce at least N cookies not yet eaten. | [{"input": "8 1", "output": "7\n \n\nIt is possible to produce 8 cookies in 7 seconds, as follows:\n\n * After 1 second: 1 cookie is done.\n * After 2 seconds: 1 more cookie is done, totaling 2. Now, Rng starts eating those 2 cookies.\n * After 3 seconds: He finishes eating the cookies, and he can now bake 2 cookies per second.\n * After 4 seconds: 2 cookies are done.\n * After 5 seconds: 2 more cookies are done, totaling 4.\n * After 6 seconds: 2 more cookies are done, totaling 6.\n * After 7 seconds: 2 more cookies are done, totaling 8.\n\n* * *"}, {"input": "1000000000000 1000000000000", "output": "1000000000000"}] |
If S is a mirror string, print `Yes`. Otherwise, print `No`.
* * * | s139026984 | Accepted | p03889 | The input is given from Standard Input in the following format:
S | t = "bpdq"
s = list(input())
print("Yes" * (s[::-1] == [t[t.index(i) - 2] for i in s]) or "No")
| Statement
You are given a string S consisting of letters `b`, `d`, `p` and `q`.
Determine whether S is a _mirror string_.
Here, a mirror string is a string S such that the following sequence of
operations on S results in the same string S:
1. Reverse the order of the characters in S.
2. Replace each occurrence of `b` by `d`, `d` by `b`, `p` by `q`, and `q` by `p`, simultaneously. | [{"input": "pdbq", "output": "Yes\n \n\n* * *"}, {"input": "ppqb", "output": "No"}] |
If S is a mirror string, print `Yes`. Otherwise, print `No`.
* * * | s111725544 | Accepted | p03889 | The input is given from Standard Input in the following format:
S | mp = {"b": "d", "d": "b", "p": "q", "q": "p"}
a = list(input())
b = list(a[::-1])
b = [mp[x] for x in b]
print("Yes" if a == b else "No")
| Statement
You are given a string S consisting of letters `b`, `d`, `p` and `q`.
Determine whether S is a _mirror string_.
Here, a mirror string is a string S such that the following sequence of
operations on S results in the same string S:
1. Reverse the order of the characters in S.
2. Replace each occurrence of `b` by `d`, `d` by `b`, `p` by `q`, and `q` by `p`, simultaneously. | [{"input": "pdbq", "output": "Yes\n \n\n* * *"}, {"input": "ppqb", "output": "No"}] |
If S is a mirror string, print `Yes`. Otherwise, print `No`.
* * * | s279398259 | Runtime Error | p03889 | The input is given from Standard Input in the following format:
S | import sys
dct = {"b": "d", "d", "b", "p": "q", "q": "p"}
S = sys.stdin.readline().strip()
rev = ""
for s in S[::-1]:
rev += dct[s]
if rev == S:
print("Yes")
else:
print("No") | Statement
You are given a string S consisting of letters `b`, `d`, `p` and `q`.
Determine whether S is a _mirror string_.
Here, a mirror string is a string S such that the following sequence of
operations on S results in the same string S:
1. Reverse the order of the characters in S.
2. Replace each occurrence of `b` by `d`, `d` by `b`, `p` by `q`, and `q` by `p`, simultaneously. | [{"input": "pdbq", "output": "Yes\n \n\n* * *"}, {"input": "ppqb", "output": "No"}] |
If S is a mirror string, print `Yes`. Otherwise, print `No`.
* * * | s181799081 | Wrong Answer | p03889 | The input is given from Standard Input in the following format:
S | s = input().split()
if s[0] == "d" and s[3] == "b":
if s[1] == "p" and s[2] == "q":
print("Yes")
elif s[1] == "q" and s[2] == "p":
print("Yes")
else:
print("No")
elif s[0] == "b" and s[3] == "d":
if s[1] == "p" and s[2] == "q":
print("Yes")
elif s[1] == "q" and s[2] == "p":
print("Yes")
else:
print("No")
elif s[0] == "p" and s[3] == "q":
if s[1] == "d" and s[2] == "b":
print("Yes")
elif s[1] == "b" and s[2] == "d":
print("Yes")
else:
print("No")
elif s[0] == "q" and s[3] == "p":
if s[1] == "d" and s[2] == "b":
print("Yes")
elif s[1] == "b" and s[2] == "d":
print("Yes")
else:
print("No")
else:
print("No")
| Statement
You are given a string S consisting of letters `b`, `d`, `p` and `q`.
Determine whether S is a _mirror string_.
Here, a mirror string is a string S such that the following sequence of
operations on S results in the same string S:
1. Reverse the order of the characters in S.
2. Replace each occurrence of `b` by `d`, `d` by `b`, `p` by `q`, and `q` by `p`, simultaneously. | [{"input": "pdbq", "output": "Yes\n \n\n* * *"}, {"input": "ppqb", "output": "No"}] |
If S is a mirror string, print `Yes`. Otherwise, print `No`.
* * * | s300750344 | Runtime Error | p03889 | The input is given from Standard Input in the following format:
S | s = input()
is s[::-1].translate(str.maketrans("bdpq","dbqp")) == s:
print("Yes")
else:
print("No") | Statement
You are given a string S consisting of letters `b`, `d`, `p` and `q`.
Determine whether S is a _mirror string_.
Here, a mirror string is a string S such that the following sequence of
operations on S results in the same string S:
1. Reverse the order of the characters in S.
2. Replace each occurrence of `b` by `d`, `d` by `b`, `p` by `q`, and `q` by `p`, simultaneously. | [{"input": "pdbq", "output": "Yes\n \n\n* * *"}, {"input": "ppqb", "output": "No"}] |
If S is a mirror string, print `Yes`. Otherwise, print `No`.
* * * | s160309915 | Wrong Answer | p03889 | The input is given from Standard Input in the following format:
S | b = "b"
d = "d"
p = "p"
q = "q"
m = [(b, d), (p, q), (d, b), (q, p)]
ans = "Yes"
s = input()
if len(s) % 2 == 1:
ans = "No"
else:
A = s[: len(s) // 2]
B = s[len(s) // 2 :]
B = B[::-1]
for i in range(len(s) // 2):
if (A[i], B[i]) in m:
continue
else:
ans = "NO"
print(ans)
| Statement
You are given a string S consisting of letters `b`, `d`, `p` and `q`.
Determine whether S is a _mirror string_.
Here, a mirror string is a string S such that the following sequence of
operations on S results in the same string S:
1. Reverse the order of the characters in S.
2. Replace each occurrence of `b` by `d`, `d` by `b`, `p` by `q`, and `q` by `p`, simultaneously. | [{"input": "pdbq", "output": "Yes\n \n\n* * *"}, {"input": "ppqb", "output": "No"}] |
In the first line, print the arranged cards provided by the Bubble Sort
algorithm. Two consecutive cards should be separated by a space character.
In the second line, print the stability ("Stable" or "Not stable") of this
output.
In the third line, print the arranged cards provided by the Selection Sort
algorithm. Two consecutive cards should be separated by a space character.
In the fourth line, print the stability ("Stable" or "Not stable") of this
output. | s328886059 | Accepted | p02261 | The first line contains an integer _N_ , the number of cards.
_N_ cards are given in the following line. Each card is represented by two
characters. Two consecutive cards are separated by a space character. | def selectionSort(arr):
icnt = 0
for i in range(0, len(arr)):
imin = i
for j in range(i + 1, len(arr)):
if arr[j][1] < arr[imin][1]:
# if arr[j] < arr[imin]:
imin = j
if imin != i:
arr[i], arr[imin] = arr[imin], arr[i]
icnt = icnt + 1
def bubbleSort(arr):
flg = True
cnt = 0
while flg:
flg = False
for i in range(len(arr) - 1, 0, -1):
if arr[i][1] < arr[i - 1][1]:
# if arr[i] < arr[i - 1]:
arr[i - 1], arr[i] = arr[i], arr[i - 1]
cnt = cnt + 1
flg = True
def combine(arr):
result = ""
for i in arr:
result = result + i[0] + str(i[1]) + " "
return result.rstrip(" ")
n = int(input())
a = list(input().split()) # [H4, C9, S4, D2, C3]
# a = list(map(int, input().split()))
b = [] # [[H,4], [C,9], [S,4], [D,2], [C,3]]
for i in range(0, len(a)):
b.append([a[i][0], int(a[i][1])])
c = b.copy()
# c = b
bubbleSort(b)
result_b = combine(b)
selectionSort(c)
result_s = combine(c)
print(result_b)
print("Stable")
print(result_s)
if result_s == result_b:
print("Stable")
else:
print("Not stable")
| Stable Sort
Let's arrange a deck of cards. There are totally 36 cards of 4 suits(S, H, C,
D) and 9 values (1, 2, ... 9). For example, 'eight of heart' is represented by
H8 and 'one of diamonds' is represented by D1.
Your task is to write a program which sorts a given set of cards in ascending
order by their values using the Bubble Sort algorithms and the Selection Sort
algorithm respectively. These algorithms should be based on the following
pseudocode:
BubbleSort(C)
1 for i = 0 to C.length-1
2 for j = C.length-1 downto i+1
3 if C[j].value < C[j-1].value
4 swap C[j] and C[j-1]
SelectionSort(C)
1 for i = 0 to C.length-1
2 mini = i
3 for j = i to C.length-1
4 if C[j].value < C[mini].value
5 mini = j
6 swap C[i] and C[mini]
Note that, indices for array elements are based on 0-origin.
For each algorithm, report the stability of the output for the given input
(instance). Here, 'stability of the output' means that: cards with the same
value appear in the output in the same order as they do in the input
(instance). | [{"input": "5\n H4 C9 S4 D2 C3", "output": "D2 C3 H4 S4 C9\n Stable\n D2 C3 S4 H4 C9\n Not stable"}, {"input": "2\n S1 H1", "output": "S1 H1\n Stable\n S1 H1\n Stable"}] |
In the first line, print the arranged cards provided by the Bubble Sort
algorithm. Two consecutive cards should be separated by a space character.
In the second line, print the stability ("Stable" or "Not stable") of this
output.
In the third line, print the arranged cards provided by the Selection Sort
algorithm. Two consecutive cards should be separated by a space character.
In the fourth line, print the stability ("Stable" or "Not stable") of this
output. | s531413753 | Accepted | p02261 | The first line contains an integer _N_ , the number of cards.
_N_ cards are given in the following line. Each card is represented by two
characters. Two consecutive cards are separated by a space character. | n = int(input())
l = input().split(" ")
L = l[:]
for k in range(n - 1):
for j in range(n - 1, 0, -1):
if L[j][1:] < L[j - 1][1:]:
L[j], L[j - 1] = L[j - 1], L[j]
m = l[k:].index(min(l[k:], key=lambda x: x[1]))
if m != 0:
l[k], l[m + k] = l[m + k], l[k]
print(*L)
print("Stable")
print(*l)
print(["Not s", "S"][l == L] + "table")
| Stable Sort
Let's arrange a deck of cards. There are totally 36 cards of 4 suits(S, H, C,
D) and 9 values (1, 2, ... 9). For example, 'eight of heart' is represented by
H8 and 'one of diamonds' is represented by D1.
Your task is to write a program which sorts a given set of cards in ascending
order by their values using the Bubble Sort algorithms and the Selection Sort
algorithm respectively. These algorithms should be based on the following
pseudocode:
BubbleSort(C)
1 for i = 0 to C.length-1
2 for j = C.length-1 downto i+1
3 if C[j].value < C[j-1].value
4 swap C[j] and C[j-1]
SelectionSort(C)
1 for i = 0 to C.length-1
2 mini = i
3 for j = i to C.length-1
4 if C[j].value < C[mini].value
5 mini = j
6 swap C[i] and C[mini]
Note that, indices for array elements are based on 0-origin.
For each algorithm, report the stability of the output for the given input
(instance). Here, 'stability of the output' means that: cards with the same
value appear in the output in the same order as they do in the input
(instance). | [{"input": "5\n H4 C9 S4 D2 C3", "output": "D2 C3 H4 S4 C9\n Stable\n D2 C3 S4 H4 C9\n Not stable"}, {"input": "2\n S1 H1", "output": "S1 H1\n Stable\n S1 H1\n Stable"}] |
In the first line, print the arranged cards provided by the Bubble Sort
algorithm. Two consecutive cards should be separated by a space character.
In the second line, print the stability ("Stable" or "Not stable") of this
output.
In the third line, print the arranged cards provided by the Selection Sort
algorithm. Two consecutive cards should be separated by a space character.
In the fourth line, print the stability ("Stable" or "Not stable") of this
output. | s714498213 | Wrong Answer | p02261 | The first line contains an integer _N_ , the number of cards.
_N_ cards are given in the following line. Each card is represented by two
characters. Two consecutive cards are separated by a space character. | # -*- coding: utf-8 -*-
def bubble_sort(cards, num):
for left in range(num - 1):
for right in range(left + 1, num):
if cards[right][1] < cards[left][1]:
cards[left], cards[right] = cards[right], cards[left]
print(list_to_str(cards))
def selection_sort(cards, num):
for head in range(num):
min_i = head
for target in range(head + 1, num):
if cards[target][1] < cards[min_i][1]:
min_i = target
cards[head], cards[min_i] = cards[min_i], cards[head]
print(list_to_str(cards))
def is_stable(before, after, num):
for i in range(num):
for j in range(i + 1, num):
for a in range(num):
for b in range(a + 1, num):
if (
before[i][1] == before[j][1]
and before[i] == after[b]
and before[j] == after[a]
):
return "Not stable"
return "Stable"
def list_to_str(l, delimiter=" "):
# The default delimiter is one space.
return delimiter.join([str(v) for v in l])
if __name__ == "__main__":
num = int(input())
cards = input().split()
cards_for_bubble = cards.copy()
cards_for_selection = cards.copy()
bubble_sort(cards_for_bubble, num)
print(is_stable(cards, cards_for_bubble, num))
selection_sort(cards_for_selection, num)
print(is_stable(cards, cards_for_selection, num))
| Stable Sort
Let's arrange a deck of cards. There are totally 36 cards of 4 suits(S, H, C,
D) and 9 values (1, 2, ... 9). For example, 'eight of heart' is represented by
H8 and 'one of diamonds' is represented by D1.
Your task is to write a program which sorts a given set of cards in ascending
order by their values using the Bubble Sort algorithms and the Selection Sort
algorithm respectively. These algorithms should be based on the following
pseudocode:
BubbleSort(C)
1 for i = 0 to C.length-1
2 for j = C.length-1 downto i+1
3 if C[j].value < C[j-1].value
4 swap C[j] and C[j-1]
SelectionSort(C)
1 for i = 0 to C.length-1
2 mini = i
3 for j = i to C.length-1
4 if C[j].value < C[mini].value
5 mini = j
6 swap C[i] and C[mini]
Note that, indices for array elements are based on 0-origin.
For each algorithm, report the stability of the output for the given input
(instance). Here, 'stability of the output' means that: cards with the same
value appear in the output in the same order as they do in the input
(instance). | [{"input": "5\n H4 C9 S4 D2 C3", "output": "D2 C3 H4 S4 C9\n Stable\n D2 C3 S4 H4 C9\n Not stable"}, {"input": "2\n S1 H1", "output": "S1 H1\n Stable\n S1 H1\n Stable"}] |
In the first line, print the arranged cards provided by the Bubble Sort
algorithm. Two consecutive cards should be separated by a space character.
In the second line, print the stability ("Stable" or "Not stable") of this
output.
In the third line, print the arranged cards provided by the Selection Sort
algorithm. Two consecutive cards should be separated by a space character.
In the fourth line, print the stability ("Stable" or "Not stable") of this
output. | s925104801 | Wrong Answer | p02261 | The first line contains an integer _N_ , the number of cards.
_N_ cards are given in the following line. Each card is represented by two
characters. Two consecutive cards are separated by a space character. | def stable(c, c_b):
for i in range(N - 1):
for j in range(i, N - 1):
if c_b[i][1] == c_b[j + 1][1]:
index1_cb = c_b.index(c_b[i])
index2_cb = c_b.index(c_b[j + 1])
index1_c = c.index(c_b[i])
index2_c = c.index(c_b[j + 1])
if index1_c < index2_c and index1_cb < index2_cb:
print("Stable")
else:
print("Not stable")
def print_list(list):
for i in range(N):
if i == N - 1:
print(list[i])
else:
print(list[i], end=" ")
N = int(input())
c = input().split()
c_b = [s for s in c]
for i in range(N):
for j in range(N - 1, i, -1):
if c_b[j][1] < c_b[j - 1][1]:
t = c_b[j]
c_b[j] = c_b[j - 1]
c_b[j - 1] = t
print_list(c_b)
stable(c, c_b)
c_s = [s for s in c]
change = "no"
for i in range(N):
cs_min = int(c_s[i][1])
for j in range(i + 1, N):
if cs_min > int(c_s[j][1]):
cs_min = int(c_s[j][1])
index = c_s.index(c_s[j])
change = "ok"
if change == "ok":
t = c_s[index]
c_s[index] = c_s[i]
c_s[i] = t
change = "no"
print_list(c_s)
stable(c, c_s)
| Stable Sort
Let's arrange a deck of cards. There are totally 36 cards of 4 suits(S, H, C,
D) and 9 values (1, 2, ... 9). For example, 'eight of heart' is represented by
H8 and 'one of diamonds' is represented by D1.
Your task is to write a program which sorts a given set of cards in ascending
order by their values using the Bubble Sort algorithms and the Selection Sort
algorithm respectively. These algorithms should be based on the following
pseudocode:
BubbleSort(C)
1 for i = 0 to C.length-1
2 for j = C.length-1 downto i+1
3 if C[j].value < C[j-1].value
4 swap C[j] and C[j-1]
SelectionSort(C)
1 for i = 0 to C.length-1
2 mini = i
3 for j = i to C.length-1
4 if C[j].value < C[mini].value
5 mini = j
6 swap C[i] and C[mini]
Note that, indices for array elements are based on 0-origin.
For each algorithm, report the stability of the output for the given input
(instance). Here, 'stability of the output' means that: cards with the same
value appear in the output in the same order as they do in the input
(instance). | [{"input": "5\n H4 C9 S4 D2 C3", "output": "D2 C3 H4 S4 C9\n Stable\n D2 C3 S4 H4 C9\n Not stable"}, {"input": "2\n S1 H1", "output": "S1 H1\n Stable\n S1 H1\n Stable"}] |
Print the maximum possible sum of the scores of the pairs.
* * * | s748505006 | Runtime Error | p03020 | Input is given from Standard Input in the following format:
N
RX_1 RY_1 RC_1
RX_2 RY_2 RC_2
\vdots
RX_N RY_N RC_N
BX_1 BY_1 BC_1
BX_2 BY_2 BC_2
\vdots
BX_N BY_N BC_N | import sys
input = sys.stdin.readline
from heapq import heappush, heappop
def min_cost_flow_dijkstra(E, s, t, f):
INF = 1 << 100
NN = N
LN = NN.bit_length()
G = [[] for _ in range(NN)]
for a, b, cap, c in E:
G[a].append([b, cap, c, len(G[b])])
G[b].append([a, 0, -c, len(G[a]) - 1])
prevv = [-1] * NN
preve = [-1] * NN
res = 0
while f > 0:
h = [0] * NN
dist = [INF] * NN
dist[s] = 0
Q = []
heappush(Q, s)
while len(Q):
x = heappop(Q)
d, v = (x >> LN), x % (1 << LN)
if dist[v] < d:
continue
for i, (w, _cap, c, r) in enumerate(G[v]):
if _cap > 0 and dist[w] > dist[v] + c + h[v] - h[w]:
dist[w] = dist[v] + c + h[v] - h[w]
prevv[w] = v
preve[w] = i
heappush(Q, (dist[w] << LN) + w)
if dist[t] == INF:
return -1
for v in range(N):
h[v] += dist[v]
d = f
v = t
while v != s:
d = min(d, G[prevv[v]][preve[v]][1])
v = prevv[v]
f -= d
res += d * dist[t]
v = t
while v != s:
G[prevv[v]][preve[v]][1] -= d
G[v][G[prevv[v]][preve[v]][3]][1] += d
v = prevv[v]
return res
E = []
N = int(input())
su = 0
inf = 1 << 31
for i in range(N):
x, y, cnt = map(int, input().split())
E.append((2 * N + 4, i, cnt, 0))
E.append((i, 2 * N, cnt, x + y + inf))
E.append((i, 2 * N + 1, cnt, x - y + inf))
E.append((i, 2 * N + 2, cnt, -x + y + inf))
E.append((i, 2 * N + 3, cnt, -x - y + inf))
su += cnt
for i in range(N):
x, y, cnt = map(int, input().split())
E.append((i + N, 2 * N + 5, cnt, 0))
E.append((2 * N, i + N, cnt, -x - y + inf))
E.append((2 * N + 1, i + N, cnt, -x + y + inf))
E.append((2 * N + 2, i + N, cnt, x - y + inf))
E.append((2 * N + 3, i + N, cnt, x + y + inf))
print(su * inf * 2 - min_cost_flow_dijkstra(E, 2 * N + 4, 2 * N + 5, su))
| Statement
Snuke is playing with red and blue balls, placing them on a two-dimensional
plane.
First, he performed N operations to place red balls. In the i-th of these
operations, he placed RC_i red balls at coordinates (RX_i,RY_i). Then, he
performed another N operations to place blue balls. In the i-th of these
operations, he placed BC_i blue balls at coordinates (BX_i,BY_i). The total
number of red balls placed and the total number of blue balls placed are
equal, that is, \sum_{i=1}^{N} RC_i = \sum_{i=1}^{N} BC_i. Let this value be
S.
Snuke will now form S pairs of red and blue balls so that every ball belongs
to exactly one pair. Let us define the _score_ of a pair of a red ball at
coordinates (rx, ry) and a blue ball at coordinates (bx, by) as |rx-bx| + |ry-
by|.
Snuke wants to maximize the sum of the scores of the pairs. Help him by
finding the maximum possible sum of the scores of the pairs. | [{"input": "2\n 0 0 1\n 3 2 1\n 2 2 1\n 5 0 1", "output": "8\n \n\nIf we pair the red ball at coordinates (0,0) and the blue ball at coordinates\n(2,2), the score of this pair is |0-2| + |0-2|=4. Then, if we pair the red\nball at coordinates (3,2) and the blue ball at coordinates (5,0), the score of\nthis pair is |3-5| + |2-0|=4. Making these two pairs results in the total\nscore of 8, which is the maximum result.\n\n* * *"}, {"input": "3\n 0 0 1\n 2 2 1\n 0 0 2\n 1 1 1\n 1 1 1\n 3 3 2", "output": "16\n \n\nSnuke may have performed multiple operations at the same coordinates.\n\n* * *"}, {"input": "10\n 582463373 690528069 8\n 621230322 318051944 4\n 356524296 974059503 6\n 372751381 111542460 9\n 392867214 581476334 6\n 606955458 513028121 5\n 882201596 791660614 9\n 250465517 91918758 3\n 618624774 406956634 6\n 426294747 736401096 5\n 974896051 888765942 5\n 726682138 336960821 3\n 715144179 82444709 6\n 599055841 501257806 6\n 390484433 962747856 4\n 912334580 219343832 8\n 570458984 648862300 6\n 638017635 572157978 10\n 435958984 585073520 7\n 445612658 234265014 6", "output": "45152033546"}] |
Print the maximum possible sum of the scores of the pairs.
* * * | s892784998 | Runtime Error | p03020 | Input is given from Standard Input in the following format:
N
RX_1 RY_1 RC_1
RX_2 RY_2 RC_2
\vdots
RX_N RY_N RC_N
BX_1 BY_1 BC_1
BX_2 BY_2 BC_2
\vdots
BX_N BY_N BC_N | import sys
read = sys.stdin.buffer.read
readline = sys.stdin.buffer.readline
readlines = sys.stdin.buffer.readlines
import numpy as np
N = int(readline())
S = np.frombuffer(b"-" + readline().rstrip(), "S1")
Q = int(readline())
query = map(int, read().split())
isD = S == b"D"
isM = S == b"M"
isC = S == b"C"
cumD = isD.cumsum(dtype=np.int64)
cumM = isM.cumsum(dtype=np.int64)
def F(K):
x = cumD.copy()
x[K:] -= cumD[:-K]
x *= isM
x[K + 1 :] -= isD[1:-K] * (cumM[K:-1] - cumM[: -K - 1])
return (x.cumsum() * isC).sum()
print("\n".join(str(F(K)) for K in query))
| Statement
Snuke is playing with red and blue balls, placing them on a two-dimensional
plane.
First, he performed N operations to place red balls. In the i-th of these
operations, he placed RC_i red balls at coordinates (RX_i,RY_i). Then, he
performed another N operations to place blue balls. In the i-th of these
operations, he placed BC_i blue balls at coordinates (BX_i,BY_i). The total
number of red balls placed and the total number of blue balls placed are
equal, that is, \sum_{i=1}^{N} RC_i = \sum_{i=1}^{N} BC_i. Let this value be
S.
Snuke will now form S pairs of red and blue balls so that every ball belongs
to exactly one pair. Let us define the _score_ of a pair of a red ball at
coordinates (rx, ry) and a blue ball at coordinates (bx, by) as |rx-bx| + |ry-
by|.
Snuke wants to maximize the sum of the scores of the pairs. Help him by
finding the maximum possible sum of the scores of the pairs. | [{"input": "2\n 0 0 1\n 3 2 1\n 2 2 1\n 5 0 1", "output": "8\n \n\nIf we pair the red ball at coordinates (0,0) and the blue ball at coordinates\n(2,2), the score of this pair is |0-2| + |0-2|=4. Then, if we pair the red\nball at coordinates (3,2) and the blue ball at coordinates (5,0), the score of\nthis pair is |3-5| + |2-0|=4. Making these two pairs results in the total\nscore of 8, which is the maximum result.\n\n* * *"}, {"input": "3\n 0 0 1\n 2 2 1\n 0 0 2\n 1 1 1\n 1 1 1\n 3 3 2", "output": "16\n \n\nSnuke may have performed multiple operations at the same coordinates.\n\n* * *"}, {"input": "10\n 582463373 690528069 8\n 621230322 318051944 4\n 356524296 974059503 6\n 372751381 111542460 9\n 392867214 581476334 6\n 606955458 513028121 5\n 882201596 791660614 9\n 250465517 91918758 3\n 618624774 406956634 6\n 426294747 736401096 5\n 974896051 888765942 5\n 726682138 336960821 3\n 715144179 82444709 6\n 599055841 501257806 6\n 390484433 962747856 4\n 912334580 219343832 8\n 570458984 648862300 6\n 638017635 572157978 10\n 435958984 585073520 7\n 445612658 234265014 6", "output": "45152033546"}] |
Print the maximum possible sum of the scores of the pairs.
* * * | s098432551 | Runtime Error | p03020 | Input is given from Standard Input in the following format:
N
RX_1 RY_1 RC_1
RX_2 RY_2 RC_2
\vdots
RX_N RY_N RC_N
BX_1 BY_1 BC_1
BX_2 BY_2 BC_2
\vdots
BX_N BY_N BC_N | import math
N, X = map(int, input().split())
B = []
L = []
U = []
for i in range(N):
b, l, u = map(int, input().split())
B += [b]
L += [l]
U += [u]
behind = 0
for i in range(N):
behind += L[i] * B[i]
gain_max = [(max(X * U[i] - B[i] * (U[i] - L[i]), X * L[i]), i) for i in range(N)]
studied = [0 for i in range(N)]
ans = 0
gain_max.sort()
takahashi_score = 0
while takahashi_score < behind:
if takahashi_score + gain_max[-1][0] < behind:
ans += X
gain = gain_max.pop(-1)
takahashi_score += gain[0]
studied[gain[1]] = 1
else: # 残り1科目で勝てる!
curr = X
for i in range(N):
if studied[i] == 0:
curr = min(
curr,
min(
(behind - takahashi_score - B[i] * L[i]) / U[i] + B[i],
(behind - takahashi_score - B[i] * L[i]) / L[i] + B[i],
),
)
ans += math.ceil(curr)
break
print(ans)
| Statement
Snuke is playing with red and blue balls, placing them on a two-dimensional
plane.
First, he performed N operations to place red balls. In the i-th of these
operations, he placed RC_i red balls at coordinates (RX_i,RY_i). Then, he
performed another N operations to place blue balls. In the i-th of these
operations, he placed BC_i blue balls at coordinates (BX_i,BY_i). The total
number of red balls placed and the total number of blue balls placed are
equal, that is, \sum_{i=1}^{N} RC_i = \sum_{i=1}^{N} BC_i. Let this value be
S.
Snuke will now form S pairs of red and blue balls so that every ball belongs
to exactly one pair. Let us define the _score_ of a pair of a red ball at
coordinates (rx, ry) and a blue ball at coordinates (bx, by) as |rx-bx| + |ry-
by|.
Snuke wants to maximize the sum of the scores of the pairs. Help him by
finding the maximum possible sum of the scores of the pairs. | [{"input": "2\n 0 0 1\n 3 2 1\n 2 2 1\n 5 0 1", "output": "8\n \n\nIf we pair the red ball at coordinates (0,0) and the blue ball at coordinates\n(2,2), the score of this pair is |0-2| + |0-2|=4. Then, if we pair the red\nball at coordinates (3,2) and the blue ball at coordinates (5,0), the score of\nthis pair is |3-5| + |2-0|=4. Making these two pairs results in the total\nscore of 8, which is the maximum result.\n\n* * *"}, {"input": "3\n 0 0 1\n 2 2 1\n 0 0 2\n 1 1 1\n 1 1 1\n 3 3 2", "output": "16\n \n\nSnuke may have performed multiple operations at the same coordinates.\n\n* * *"}, {"input": "10\n 582463373 690528069 8\n 621230322 318051944 4\n 356524296 974059503 6\n 372751381 111542460 9\n 392867214 581476334 6\n 606955458 513028121 5\n 882201596 791660614 9\n 250465517 91918758 3\n 618624774 406956634 6\n 426294747 736401096 5\n 974896051 888765942 5\n 726682138 336960821 3\n 715144179 82444709 6\n 599055841 501257806 6\n 390484433 962747856 4\n 912334580 219343832 8\n 570458984 648862300 6\n 638017635 572157978 10\n 435958984 585073520 7\n 445612658 234265014 6", "output": "45152033546"}] |
Print the maximum possible sum of the scores of the pairs.
* * * | s586299590 | Accepted | p03020 | Input is given from Standard Input in the following format:
N
RX_1 RY_1 RC_1
RX_2 RY_2 RC_2
\vdots
RX_N RY_N RC_N
BX_1 BY_1 BC_1
BX_2 BY_2 BC_2
\vdots
BX_N BY_N BC_N | import sys
read = sys.stdin.buffer.read
readline = sys.stdin.buffer.readline
readlines = sys.stdin.buffer.readlines
from heapq import heappop, heappush
N = int(readline())
m = map(int, read().split())
data = list(zip(m, m, m))
R = data[:N]
B = data[N:]
class MinCostFlow:
"""
最小費用流。負辺がないと仮定して、BellmanFordを省略している。
"""
def __init__(self, N, source, sink):
self.N = N
self.G = [[] for _ in range(N)]
self.source = source
self.sink = sink
def add_edge(self, fr, to, cap, cost):
n1 = len(self.G[fr])
n2 = len(self.G[to])
self.G[fr].append([to, cap, cost, n2])
self.G[to].append([fr, 0, -cost, n1])
def MinCost(self, flow, negative_edge=False):
if negative_edge:
raise ValueError
N = self.N
G = self.G
source = self.source
sink = self.sink
INF = 10**18
prev_v = [0] * N
prev_e = [0] * N # 経路復元用
H = [0] * N # potential
mincost = 0
while flow:
dist = [INF] * N
dist[source] = 0
q = [source]
mask = (1 << 20) - 1
while q:
x = heappop(q)
dv = x >> 20
v = x & mask
if dist[v] < dv:
continue
if v == sink:
break
for i, (w, cap, cost, rev) in enumerate(G[v]):
dw = dist[v] + cost + H[v] - H[w]
if (not cap) or (dist[w] <= dw):
continue
dist[w] = dw
prev_v[w] = v
prev_e[w] = i
heappush(q, (dw << 20) + w)
# if dist[sink] == INF:
# raise Exception('No Flow Exists')
# ポテンシャルの更新
for v, d in enumerate(dist):
H[v] += d
# 流せる量を取得する
d = flow
v = sink
while v != source:
pv = prev_v[v]
pe = prev_e[v]
cap = G[pv][pe][1]
if d > cap:
d = cap
v = pv
# 流す
mincost += d * H[sink]
flow -= d
v = sink
while v != source:
pv = prev_v[v]
pe = prev_e[v]
G[pv][pe][1] -= d
rev = G[pv][pe][3]
G[v][rev][1] += d
v = pv
return mincost
source = N + N
sink = N + N + 1
V1 = N + N + 2
V2 = N + N + 3
V3 = N + N + 4
V4 = N + N + 5
G = MinCostFlow(N + N + 6, source=source, sink=sink)
base = 10**9 * 2 # 各辺に上乗せしておく -> 最後に引く
INF = 10**18
flow = 0
for i, (x, y, c) in enumerate(R):
flow += c
G.add_edge(fr=source, to=i, cap=c, cost=0)
G.add_edge(i, V1, INF, base - x - y)
G.add_edge(i, V2, INF, base - x + y)
G.add_edge(i, V3, INF, base + x - y)
G.add_edge(i, V4, INF, base + x + y)
for i, (x, y, c) in enumerate(B, N):
G.add_edge(fr=i, to=sink, cap=c, cost=0)
G.add_edge(V1, i, INF, base + x + y)
G.add_edge(V2, i, INF, base + x - y)
G.add_edge(V3, i, INF, base - x + y)
G.add_edge(V4, i, INF, base - x - y)
cost = G.MinCost(flow)
answer = base * (2 * flow) - cost
print(answer)
| Statement
Snuke is playing with red and blue balls, placing them on a two-dimensional
plane.
First, he performed N operations to place red balls. In the i-th of these
operations, he placed RC_i red balls at coordinates (RX_i,RY_i). Then, he
performed another N operations to place blue balls. In the i-th of these
operations, he placed BC_i blue balls at coordinates (BX_i,BY_i). The total
number of red balls placed and the total number of blue balls placed are
equal, that is, \sum_{i=1}^{N} RC_i = \sum_{i=1}^{N} BC_i. Let this value be
S.
Snuke will now form S pairs of red and blue balls so that every ball belongs
to exactly one pair. Let us define the _score_ of a pair of a red ball at
coordinates (rx, ry) and a blue ball at coordinates (bx, by) as |rx-bx| + |ry-
by|.
Snuke wants to maximize the sum of the scores of the pairs. Help him by
finding the maximum possible sum of the scores of the pairs. | [{"input": "2\n 0 0 1\n 3 2 1\n 2 2 1\n 5 0 1", "output": "8\n \n\nIf we pair the red ball at coordinates (0,0) and the blue ball at coordinates\n(2,2), the score of this pair is |0-2| + |0-2|=4. Then, if we pair the red\nball at coordinates (3,2) and the blue ball at coordinates (5,0), the score of\nthis pair is |3-5| + |2-0|=4. Making these two pairs results in the total\nscore of 8, which is the maximum result.\n\n* * *"}, {"input": "3\n 0 0 1\n 2 2 1\n 0 0 2\n 1 1 1\n 1 1 1\n 3 3 2", "output": "16\n \n\nSnuke may have performed multiple operations at the same coordinates.\n\n* * *"}, {"input": "10\n 582463373 690528069 8\n 621230322 318051944 4\n 356524296 974059503 6\n 372751381 111542460 9\n 392867214 581476334 6\n 606955458 513028121 5\n 882201596 791660614 9\n 250465517 91918758 3\n 618624774 406956634 6\n 426294747 736401096 5\n 974896051 888765942 5\n 726682138 336960821 3\n 715144179 82444709 6\n 599055841 501257806 6\n 390484433 962747856 4\n 912334580 219343832 8\n 570458984 648862300 6\n 638017635 572157978 10\n 435958984 585073520 7\n 445612658 234265014 6", "output": "45152033546"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s032355888 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | # coding=utf-8
i = int(input())
rrr = []
for d in range(i):
r = [int(input())]
rrr += r
s = len(set(rrr))
print(s)
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s221322866 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
List=[int(input()) for i in range(n)]
ans = 0
while True
for i,j in range(n):
if i == j:
ans +=1
print(n-ans) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s989967520 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N=int(input())
A=[input() i in range(N)]
B=[]
while len(A)!=0:
if A[0] not in B:
B.append(A[0])
A.popleft()
print(len(B)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s979610225 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
list_a = [int(input()) for i in range(N)]
s = []
for i in list_a:
if s.count(i) == 0
s.append(i)
print(len(s)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s998558135 | Wrong Answer | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
ls = [int(input()) for i in range(N)]
ls = sorted(ls, reverse=True)
A = 0
i = 0
while i < N:
if ls[i - 1] == ls[i]:
A = A + 1
i = i + 1
print(N - A)
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s736929003 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | # -*- coding: utf-8 -*-
#############
# Libraries #
#############
import sys
input = sys.stdin.readline
import math
# from math import gcd
import bisect
from collections import defaultdict
from collections import deque
from functools import lru_cache
#############
# Constants #
#############
MOD = 10**9 + 7
INF = float("inf")
#############
# Functions #
#############
######INPUT######
def inputI():
return int(input().strip())
def inputS():
return input().strip()
def inputIL():
return list(map(int, input().split()))
def inputSL():
return list(map(str, input().split()))
def inputILs(n):
return list(int(input()) for _ in range(n))
def inputSLs(n):
return list(input().strip() for _ in range(n))
def inputILL(n):
return [list(map(int, input().split())) for _ in range(n)]
def inputSLL(n):
return [list(map(str, input().split())) for _ in range(n)]
######OUTPUT######
def Yes():
print("Yes")
return
def No():
print("No")
return
#####Inverse#####
def inv(n):
return pow(n, MOD - 2, MOD)
######Combination######
kaijo_memo = []
def kaijo(n):
if len(kaijo_memo) > n:
return kaijo_memo[n]
if len(kaijo_memo) == 0:
kaijo_memo.append(1)
while len(kaijo_memo) <= n:
kaijo_memo.append(kaijo_memo[-1] * len(kaijo_memo) % MOD)
return kaijo_memo[n]
gyaku_kaijo_memo = []
def gyaku_kaijo(n):
if len(gyaku_kaijo_memo) > n:
return gyaku_kaijo_memo[n]
if len(gyaku_kaijo_memo) == 0:
gyaku_kaijo_memo.append(1)
while len(gyaku_kaijo_memo) <= n:
gyaku_kaijo_memo.append(
gyaku_kaijo_memo[-1] * pow(len(gyaku_kaijo_memo), MOD - 2, MOD) % MOD
)
return gyaku_kaijo_memo[n]
def nCr(n, r):
if n == r:
return 1
if n < r or r < 0:
return 0
ret = 1
ret = ret * kaijo(n) % MOD
ret = ret * gyaku_kaijo(r) % MOD
ret = ret * gyaku_kaijo(n - r) % MOD
return ret
######Factorization######
def factorization(n):
arr = []
temp = n
for i in range(2, int(-(-(n**0.5) // 1)) + 1):
if temp % i == 0:
cnt = 0
while temp % i == 0:
cnt += 1
temp //= i
arr.append([i, cnt])
if temp != 1:
arr.append([temp, 1])
if arr == []:
arr.append([n, 1])
return arr
#####MakeDivisors######
def make_divisors(n):
divisors = []
for i in range(1, int(n**0.5) + 1):
if n % i == 0:
divisors.append(i)
if i != n // i:
divisors.append(n // i)
return divisors
#####LCM#####
def lcm(a, b):
return a * b // gcd(a, b)
#####BitCount#####
def count_bit(n):
count = 0
while n:
n &= n - 1
count += 1
return count
#####ChangeBase#####
def Base_10_to_n(X, n):
if X // n:
return Base_10_to_n(X // n, n) + [X % n]
return [X % n]
def Base_n_to_10(X, n):
return sum(int(str(X)[-i]) * n**i for i in range(len(str(X))))
#####IntLog#####
def int_log(n, a):
count = 0
while n >= a:
n //= a
count += 1
return count
#############
# Main Code #
#############
N = inputI()
d = inputILs(N)
print(len(set(d)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s449873619 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | import sys
from random import randint
# from typing import TypeVar, Tuple, List
finput = sys.stdin.readline
# K = TypeVar("K")
class ListNode:
def __init__(self, key, next_=None):
self.key, self.next = key, next_
class HashSetLinkedList:
def __init__(self):
self.__head = ListNode(None)
self.__tail = self.__head
def __repr__(self):
keys = [str(key) if type(key) != str else "'" + key + "'" for key in self]
return "->" + " -> ".join(keys)
def find(self, key):
cur_node = self.__head.next
while cur_node:
if cur_node.key == key:
return True
cur_node = cur_node.next
return False
def insert(self, key):
if not self.find(key):
self.__tail.next = ListNode(key)
self.__tail = self.__tail.next
return 1
return 0
def delete(self, key):
cur_node = self.__head
while cur_node.next:
if cur_node.next.key == key:
cur_node.next = cur_node.next.next
return
cur_node = cur_node.next
def __iter__(self):
self._cur_node = self.__head.next
return self
def __next__(self):
if not self._cur_node:
raise StopIteration()
key = self._cur_node.key
self._cur_node = self._cur_node.next
return key
class HashSet:
SCALE_FACTOR = 2
SHRINKAGE_THRESHOLD = 4
PRIME_NUMBER = (1 << 31) - 1
def __init__(self, capacity=16):
self.__arr = [HashSetLinkedList() for _ in range(capacity)]
self.__capacity = capacity
self.__num_items = 0
self.__param1, self.__param2 = randint(0, self.PRIME_NUMBER - 1), randint(
0, self.PRIME_NUMBER - 1
)
def __repr__(self):
return (
"{"
+ ", ".join(
(str(key) if type(key) != str else "'" + key + "'")
for linked_list in self.__arr
for key in linked_list
)
+ "}"
)
def __len__(self):
return self.__num_items
def _range_hash(self, prehashed_key):
return (self.__param1 * prehashed_key + self.__param2) % self.__capacity
def _resize(self, enlarge=True):
if enlarge:
self.__capacity *= self.SCALE_FACTOR
else:
self.__capacity //= self.SCALE_FACTOR
new_arr = [HashSetLinkedList() for _ in range(self.__capacity)]
for linked_list in self.__arr:
for key in linked_list:
new_idx = self._range_hash(hash(key))
new_arr[new_idx].insert(key)
self.__arr = new_arr
def add(self, key):
idx = self._range_hash(hash(key))
self.__num_items += self.__arr[idx].insert(key)
# Double the capacity.
if self.__num_items == self.__capacity:
self._resize(enlarge=True)
def find(self, key):
idx = self._range_hash(hash(key))
return self.__arr[idx].find(key)
def __contains__(self, key):
return self.find(key)
def discard(self, key):
idx = self._range_hash(hash(key))
self.__arr[idx].delete(key)
self.__num_items -= 1
# Halve the capacity when #items is less than or equal to
# the capacity / SHRINKAGE_THRESHOLD.
if self.__num_items * self.SHRINKAGE_THRESHOLD <= self.__capacity:
self._resize(enlarge=False)
N = int(finput())
d_list = [int(finput()) for _ in range(N)]
d_set = HashSet()
for d in d_list:
d_set.add(d)
# d_set = set(d_list)
print(len(d_set))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s264397381 | Wrong Answer | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | moti_total = int(input())
moti = []
for n in range(moti_total):
moti.append(int(input()))
moti.sort()
tower = 1
for n in range(moti_total - 1):
if moti[n] is not moti[n + 1]:
print("n " + str(moti[n]) + " n2 " + str(moti[n + 1]))
tower += 1
print(tower)
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s512620072 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
s = set()
for i in range(n):
s.add(int(input())
print(min(3,len(s))) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s275883386 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
cake = [input() for i range(n)]
print(len(set(cake)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s918130478 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set([input() for i in range(int(input()))])))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s344131135 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
A = sorted[input() for _ in range(N)]
print(len(set(A)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s152481947 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
cake = input() for i range(n)
print(len(set(cake)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s162555935 | Wrong Answer | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set(input for i in range(int(input())))))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s305897843 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
d = [int(input()) for i in range(1, N + 1)]
d = sorted(d)
moti = 0
x = []
for i in d:
if i > moti:
x.append(i)
moti = i
print(len(x))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s047042277 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n=int(input())
list=[input() for i in range(n)]
a = []
for i in range(n):
a.append(list.count(i))
print(len(set((a)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s146841769 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
M = list()
for i in range(N):
M.append(int(input())
M = list(set(M))
ans = len(M)
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s664863122 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
m = [int(input()) for i in range(n)]
mso = sorted(m)
count = 0
for s in range(1,n):
if mso[s] == mso[s-1]
count += 1
print(n-count) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s522813265 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N= int(input())
d = list()
for i in range(N):
d.append(int(input())
d_set = set(d)
d_list = list(d_set)
d_list.sort()
print(len(d_list)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s087639096 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
num = {}
for i in range(n):
a = input()
num[a]=True
print(num.keys().count()) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s781760787 | Wrong Answer | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | b = int(input())
nums = [int(input()) for i in range(b)]
print(len(set(nums)) if not len(set(nums)) == 1 else "0")
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s921353164 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | # Author: cr4zjh0bp
# Created: Thu Mar 12 19:59:40 UTC 2020
import sys
stdin = sys.stdin
inf = 1 << 60
mod = 1000000007
ni = lambda: int(ns())
nin = lambda y: [ni() for _ in range(y)]
na = lambda: list(map(int, stdin.readline().split()))
nan = lambda y: [na() for _ in range(y)]
nf = lambda: float(ns())
nfn = lambda y: [nf() for _ in range(y)]
nfa = lambda: list(map(float, stdin.readline().split()))
nfan = lambda y: [nfa() for _ in range(y)]
ns = lambda: stdin.readline().rstrip()
nsn = lambda y: [ns() for _ in range(y)]
ncl = lambda y: [list(ns()) for _ in range(y)]
nas = lambda: stdin.readline().split()
N = ni()
D = nin(N)
D.sort()
ans = 1
for i in range(N - 1):
if D[i] < D[i + 1]:
ans += 1
print(ans)
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s810603258 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
num_list = [int(input()) for i in range(n)]
result_list = []
for num in num_list:
if num not in result_list:
result_list.append(num)
print(len(result_list))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s890292567 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | import sys
dList = list()
for i, d in sys.stdin:
if i <> 0: # 1行目の行数情報はいらないので読み飛ばす
dList.append(d)
print(len(set(dList)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s518270650 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | a, b = map(int, input().split())
for s in range(b // 10000 + 1):
try:
for t in range(b // 5000 + 1):
r = b - s - t
if 10000 * s + 5000 * t + 1000 * r == b and s + t + r == a:
print(s, t, r)
exit()
except ZeroDivisionError:
continue
print(-1, -1, -1)
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s276961915 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | #枚数
paper = int(input())
#餅リスト
moti_list = []
li_uniq = []
#取得
for w in range(paper):
paper = int(input())
moti_list.append(paper)
print(len(moti_list)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s602721353 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
l = list(map(int,input().split() for i in range(N))
l = set(l)
print(len(l)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s210007189 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
a = []
for i in range(n):
x = int(input())
a.append(x)
print(len(set(a)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s714254042 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
list_d = [int(input()) for i int range(n)]
print(len(set(lst))) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s191382302 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | times = int(input())
num = list(map(int,[input() for _ in range(times)]))
print(len(set(num)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s361759908 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = input()
d = []
for i in range(N):
a.append(input())
print(len(list(set(li))) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s006050554 | Wrong Answer | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | s = input()
s = int(s)
input_data = [int(input()) for _ in range(s)]
print(len(list(input_data)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s370768460 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | rows = int(input())
x = [input() for i in range(rows)]
print(len(set(x)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s116030064 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set(input() for i in range(int(input())))))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s388021952 | Wrong Answer | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set(open(0).readlines()[1:])) - 1)
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s410176335 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n=int(input())
d={input();1for i in range(n)}
print(sum(d.values())) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s240367558 | Wrong Answer | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(set([int(input()) for i in range(int(input()))]))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s413298119 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set([int(input()) for _ in range(input())])))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s803397691 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | len(set([int(input()) for _ in range(input())])) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s863563134 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = int(input())
d = [input() for i in range(N)]
print(len((set(d))) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s773247496 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set(input() for i in range(int(input())))) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s696807867 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
S = set([int(input()) for in range(n)])
print(len(S)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s155311983 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | N = input()
d = [input() for i in range(N)]
print(len(set(d)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s303832282 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = int(input())
print(len(set(int(input) for _ in range(n))) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s128421624 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set(int(input()) for _ in range(int(input())))) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s488749496 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | A, B = input().split()
print("YNeos"[int(A + B) ** 0.5 % 1 != 0 :: 2])
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s628617671 | Runtime Error | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | n = input()
S = set([int(input()) for in range(n)])
print(len(S)) | Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s748564931 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(set([int(input()) for i in range(int(input()))])))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s062481027 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | times = int(input())
num = list(map(int, [input() for _ in range(times)]))
print(len(set(num)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s306313545 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | a, *b = open(0)
print(len(set(b)))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print the maximum number of layers in a kagami mochi that can be made.
* * * | s604322139 | Accepted | p03470 | Input is given from Standard Input in the following format:
N
d_1
:
d_N | print(len(sorted(set([int(input()) for _ in [0] * int(input())]))))
| Statement
An _X -layered kagami mochi_ (X ≥ 1) is a pile of X round mochi (rice cake)
stacked vertically where each mochi (except the bottom one) has a smaller
diameter than that of the mochi directly below it. For example, if you stack
three mochi with diameters of 10, 8 and 6 centimeters from bottom to top in
this order, you have a 3-layered kagami mochi; if you put just one mochi, you
have a 1-layered kagami mochi.
Lunlun the dachshund has N round mochi, and the diameter of the i-th mochi is
d_i centimeters. When we make a kagami mochi using some or all of them, at
most how many layers can our kagami mochi have? | [{"input": "4\n 10\n 8\n 8\n 6", "output": "3\n \n\nIf we stack the mochi with diameters of 10, 8 and 6 centimeters from bottom to\ntop in this order, we have a 3-layered kagami mochi, which is the maximum\nnumber of layers.\n\n* * *"}, {"input": "3\n 15\n 15\n 15", "output": "1\n \n\nWhen all the mochi have the same diameter, we can only have a 1-layered kagami\nmochi.\n\n* * *"}, {"input": "7\n 50\n 30\n 50\n 100\n 50\n 80\n 30", "output": "4"}] |
Print one longest string that is a subsequence of both s and t. If there are
multiple such strings, any of them will be accepted.
* * * | s731828258 | Accepted | p03165 | Input is given from Standard Input in the following format:
s
t | # -*- coding: utf-8 -*-
#############
# Libraries #
#############
import sys
input = sys.stdin.readline
import math
# from math import gcd
import bisect
import heapq
from collections import defaultdict
from collections import deque
from collections import Counter
from functools import lru_cache
#############
# Constants #
#############
MOD = 10**9 + 7
INF = float("inf")
AZ = "abcdefghijklmnopqrstuvwxyz"
#############
# Functions #
#############
######INPUT######
def I():
return int(input().strip())
def S():
return input().strip()
def IL():
return list(map(int, input().split()))
def SL():
return list(map(str, input().split()))
def ILs(n):
return list(int(input()) for _ in range(n))
def SLs(n):
return list(input().strip() for _ in range(n))
def ILL(n):
return [list(map(int, input().split())) for _ in range(n)]
def SLL(n):
return [list(map(str, input().split())) for _ in range(n)]
######OUTPUT######
def P(arg):
print(arg)
return
def Y():
print("Yes")
return
def N():
print("No")
return
def E():
exit()
def PE(arg):
print(arg)
exit()
def YE():
print("Yes")
exit()
def NE():
print("No")
exit()
#####Shorten#####
def DD(arg):
return defaultdict(arg)
#####Inverse#####
def inv(n):
return pow(n, MOD - 2, MOD)
######Combination######
kaijo_memo = []
def kaijo(n):
if len(kaijo_memo) > n:
return kaijo_memo[n]
if len(kaijo_memo) == 0:
kaijo_memo.append(1)
while len(kaijo_memo) <= n:
kaijo_memo.append(kaijo_memo[-1] * len(kaijo_memo) % MOD)
return kaijo_memo[n]
gyaku_kaijo_memo = []
def gyaku_kaijo(n):
if len(gyaku_kaijo_memo) > n:
return gyaku_kaijo_memo[n]
if len(gyaku_kaijo_memo) == 0:
gyaku_kaijo_memo.append(1)
while len(gyaku_kaijo_memo) <= n:
gyaku_kaijo_memo.append(
gyaku_kaijo_memo[-1] * pow(len(gyaku_kaijo_memo), MOD - 2, MOD) % MOD
)
return gyaku_kaijo_memo[n]
def nCr(n, r):
if n == r:
return 1
if n < r or r < 0:
return 0
ret = 1
ret = ret * kaijo(n) % MOD
ret = ret * gyaku_kaijo(r) % MOD
ret = ret * gyaku_kaijo(n - r) % MOD
return ret
######Factorization######
def factorization(n):
arr = []
temp = n
for i in range(2, int(-(-(n**0.5) // 1)) + 1):
if temp % i == 0:
cnt = 0
while temp % i == 0:
cnt += 1
temp //= i
arr.append([i, cnt])
if temp != 1:
arr.append([temp, 1])
if arr == []:
arr.append([n, 1])
return arr
#####MakeDivisors######
def make_divisors(n):
divisors = []
for i in range(1, int(n**0.5) + 1):
if n % i == 0:
divisors.append(i)
if i != n // i:
divisors.append(n // i)
return divisors
#####MakePrimes######
def make_primes(N):
max = int(math.sqrt(N))
seachList = [i for i in range(2, N + 1)]
primeNum = []
while seachList[0] <= max:
primeNum.append(seachList[0])
tmp = seachList[0]
seachList = [i for i in seachList if i % tmp != 0]
primeNum.extend(seachList)
return primeNum
#####GCD#####
def gcd(a, b):
while b:
a, b = b, a % b
return a
#####LCM#####
def lcm(a, b):
return a * b // gcd(a, b)
#####BitCount#####
def count_bit(n):
count = 0
while n:
n &= n - 1
count += 1
return count
#####ChangeBase#####
def base_10_to_n(X, n):
if X // n:
return base_10_to_n(X // n, n) + [X % n]
return [X % n]
def base_n_to_10(X, n):
return sum(int(str(X)[-i - 1]) * n**i for i in range(len(str(X))))
def base_10_to_n_without_0(X, n):
X -= 1
if X // n:
return base_10_to_n_without_0(X // n, n) + [X % n]
return [X % n]
#####IntLog#####
def int_log(n, a):
count = 0
while n >= a:
n //= a
count += 1
return count
#############
# Main Code #
#############
A = S()
B = S()
def lcs(S, T):
L1 = len(S)
L2 = len(T)
dp = [[0] * (L2 + 1) for i in range(L1 + 1)]
for i in range(L1 - 1, -1, -1):
for j in range(L2 - 1, -1, -1):
r = max(dp[i + 1][j], dp[i][j + 1])
if S[i] == T[j]:
r = max(r, dp[i + 1][j + 1] + 1)
dp[i][j] = r
# return dp[0][0]
# dp[0][0] が長さの解
# ここからは復元処理
res = []
i = 0
j = 0
while i < L1 and j < L2:
if S[i] == T[j]:
res.append(S[i])
i += 1
j += 1
elif dp[i][j] == dp[i + 1][j]:
i += 1
elif dp[i][j] == dp[i][j + 1]:
j += 1
return "".join(res)
print(lcs(A, B))
| Statement
You are given strings s and t. Find one longest string that is a subsequence
of both s and t. | [{"input": "axyb\n abyxb", "output": "axb\n \n\nThe answer is `axb` or `ayb`; either will be accepted.\n\n* * *"}, {"input": "aa\n xayaz", "output": "aa\n \n\n* * *"}, {"input": "a\n z", "output": "The answer is `` (an empty string).\n\n* * *"}, {"input": "abracadabra\n avadakedavra", "output": "aaadara"}] |