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248
|
A
|
Cupboards
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
One foggy Stockholm morning, Karlsson decided to snack on some jam in his friend Lillebror Svantenson's house. Fortunately for Karlsson, there wasn't anybody in his friend's house. Karlsson was not going to be hungry any longer, so he decided to get some food in the house.
Karlsson's gaze immediately fell on *n* wooden cupboards, standing in the kitchen. He immediately realized that these cupboards have hidden jam stocks. Karlsson began to fly greedily around the kitchen, opening and closing the cupboards' doors, grab and empty all the jars of jam that he could find.
And now all jars of jam are empty, Karlsson has had enough and does not want to leave traces of his stay, so as not to let down his friend. Each of the cupboards has two doors: the left one and the right one. Karlsson remembers that when he rushed to the kitchen, all the cupboards' left doors were in the same position (open or closed), similarly, all the cupboards' right doors were in the same position (open or closed). Karlsson wants the doors to meet this condition as well by the time the family returns. Karlsson does not remember the position of all the left doors, also, he cannot remember the position of all the right doors. Therefore, it does not matter to him in what position will be all left or right doors. It is important to leave all the left doors in the same position, and all the right doors in the same position. For example, all the left doors may be closed, and all the right ones may be open.
Karlsson needs one second to open or close a door of a cupboard. He understands that he has very little time before the family returns, so he wants to know the minimum number of seconds *t*, in which he is able to bring all the cupboard doors in the required position.
Your task is to write a program that will determine the required number of seconds *t*.
|
The first input line contains a single integer *n* — the number of cupboards in the kitchen (2<=≤<=*n*<=≤<=104). Then follow *n* lines, each containing two integers *l**i* and *r**i* (0<=≤<=*l**i*,<=*r**i*<=≤<=1). Number *l**i* equals one, if the left door of the *i*-th cupboard is opened, otherwise number *l**i* equals zero. Similarly, number *r**i* equals one, if the right door of the *i*-th cupboard is opened, otherwise number *r**i* equals zero.
The numbers in the lines are separated by single spaces.
|
In the only output line print a single integer *t* — the minimum number of seconds Karlsson needs to change the doors of all cupboards to the position he needs.
|
[
"5\n0 1\n1 0\n0 1\n1 1\n0 1\n"
] |
[
"3\n"
] |
none
| 500
|
[
{
"input": "5\n0 1\n1 0\n0 1\n1 1\n0 1",
"output": "3"
},
{
"input": "2\n0 0\n0 0",
"output": "0"
},
{
"input": "3\n0 1\n1 1\n1 1",
"output": "1"
},
{
"input": "8\n0 1\n1 0\n0 1\n1 1\n0 1\n1 0\n0 1\n1 0",
"output": "7"
},
{
"input": "8\n1 0\n1 0\n1 0\n0 1\n0 1\n1 1\n1 1\n0 1",
"output": "6"
},
{
"input": "15\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0",
"output": "0"
},
{
"input": "5\n1 0\n1 0\n1 0\n0 1\n0 1",
"output": "4"
}
] | 1,693,650,029
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 57
| 372
| 5,324,800
|
n = int(input())
left = right = 0
for i in range(n):
line = input()
x = list(map(int, line.split()))
if x[0] == 1:
left += 1
if x[1] == 1:
right += 1
a = n-left
b = left
c = n - right
d = right
print(min(a,b) + min(c,d))
|
Title: Cupboards
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One foggy Stockholm morning, Karlsson decided to snack on some jam in his friend Lillebror Svantenson's house. Fortunately for Karlsson, there wasn't anybody in his friend's house. Karlsson was not going to be hungry any longer, so he decided to get some food in the house.
Karlsson's gaze immediately fell on *n* wooden cupboards, standing in the kitchen. He immediately realized that these cupboards have hidden jam stocks. Karlsson began to fly greedily around the kitchen, opening and closing the cupboards' doors, grab and empty all the jars of jam that he could find.
And now all jars of jam are empty, Karlsson has had enough and does not want to leave traces of his stay, so as not to let down his friend. Each of the cupboards has two doors: the left one and the right one. Karlsson remembers that when he rushed to the kitchen, all the cupboards' left doors were in the same position (open or closed), similarly, all the cupboards' right doors were in the same position (open or closed). Karlsson wants the doors to meet this condition as well by the time the family returns. Karlsson does not remember the position of all the left doors, also, he cannot remember the position of all the right doors. Therefore, it does not matter to him in what position will be all left or right doors. It is important to leave all the left doors in the same position, and all the right doors in the same position. For example, all the left doors may be closed, and all the right ones may be open.
Karlsson needs one second to open or close a door of a cupboard. He understands that he has very little time before the family returns, so he wants to know the minimum number of seconds *t*, in which he is able to bring all the cupboard doors in the required position.
Your task is to write a program that will determine the required number of seconds *t*.
Input Specification:
The first input line contains a single integer *n* — the number of cupboards in the kitchen (2<=≤<=*n*<=≤<=104). Then follow *n* lines, each containing two integers *l**i* and *r**i* (0<=≤<=*l**i*,<=*r**i*<=≤<=1). Number *l**i* equals one, if the left door of the *i*-th cupboard is opened, otherwise number *l**i* equals zero. Similarly, number *r**i* equals one, if the right door of the *i*-th cupboard is opened, otherwise number *r**i* equals zero.
The numbers in the lines are separated by single spaces.
Output Specification:
In the only output line print a single integer *t* — the minimum number of seconds Karlsson needs to change the doors of all cupboards to the position he needs.
Demo Input:
['5\n0 1\n1 0\n0 1\n1 1\n0 1\n']
Demo Output:
['3\n']
Note:
none
|
```python
n = int(input())
left = right = 0
for i in range(n):
line = input()
x = list(map(int, line.split()))
if x[0] == 1:
left += 1
if x[1] == 1:
right += 1
a = n-left
b = left
c = n - right
d = right
print(min(a,b) + min(c,d))
```
| 3
|
|
69
|
A
|
Young Physicist
|
PROGRAMMING
| 1,000
|
[
"implementation",
"math"
] |
A. Young Physicist
|
2
|
256
|
A guy named Vasya attends the final grade of a high school. One day Vasya decided to watch a match of his favorite hockey team. And, as the boy loves hockey very much, even more than physics, he forgot to do the homework. Specifically, he forgot to complete his physics tasks. Next day the teacher got very angry at Vasya and decided to teach him a lesson. He gave the lazy student a seemingly easy task: You are given an idle body in space and the forces that affect it. The body can be considered as a material point with coordinates (0; 0; 0). Vasya had only to answer whether it is in equilibrium. "Piece of cake" — thought Vasya, we need only to check if the sum of all vectors is equal to 0. So, Vasya began to solve the problem. But later it turned out that there can be lots and lots of these forces, and Vasya can not cope without your help. Help him. Write a program that determines whether a body is idle or is moving by the given vectors of forces.
|
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100), then follow *n* lines containing three integers each: the *x**i* coordinate, the *y**i* coordinate and the *z**i* coordinate of the force vector, applied to the body (<=-<=100<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=100).
|
Print the word "YES" if the body is in equilibrium, or the word "NO" if it is not.
|
[
"3\n4 1 7\n-2 4 -1\n1 -5 -3\n",
"3\n3 -1 7\n-5 2 -4\n2 -1 -3\n"
] |
[
"NO",
"YES"
] |
none
| 500
|
[
{
"input": "3\n4 1 7\n-2 4 -1\n1 -5 -3",
"output": "NO"
},
{
"input": "3\n3 -1 7\n-5 2 -4\n2 -1 -3",
"output": "YES"
},
{
"input": "10\n21 32 -46\n43 -35 21\n42 2 -50\n22 40 20\n-27 -9 38\n-4 1 1\n-40 6 -31\n-13 -2 34\n-21 34 -12\n-32 -29 41",
"output": "NO"
},
{
"input": "10\n25 -33 43\n-27 -42 28\n-35 -20 19\n41 -42 -1\n49 -39 -4\n-49 -22 7\n-19 29 41\n8 -27 -43\n8 34 9\n-11 -3 33",
"output": "NO"
},
{
"input": "10\n-6 21 18\n20 -11 -8\n37 -11 41\n-5 8 33\n29 23 32\n30 -33 -11\n39 -49 -36\n28 34 -49\n22 29 -34\n-18 -6 7",
"output": "NO"
},
{
"input": "10\n47 -2 -27\n0 26 -14\n5 -12 33\n2 18 3\n45 -30 -49\n4 -18 8\n-46 -44 -41\n-22 -10 -40\n-35 -21 26\n33 20 38",
"output": "NO"
},
{
"input": "13\n-3 -36 -46\n-11 -50 37\n42 -11 -15\n9 42 44\n-29 -12 24\n3 9 -40\n-35 13 50\n14 43 18\n-13 8 24\n-48 -15 10\n50 9 -50\n21 0 -50\n0 0 -6",
"output": "YES"
},
{
"input": "14\n43 23 17\n4 17 44\n5 -5 -16\n-43 -7 -6\n47 -48 12\n50 47 -45\n2 14 43\n37 -30 15\n4 -17 -11\n17 9 -45\n-50 -3 -8\n-50 0 0\n-50 0 0\n-16 0 0",
"output": "YES"
},
{
"input": "13\n29 49 -11\n38 -11 -20\n25 1 -40\n-11 28 11\n23 -19 1\n45 -41 -17\n-3 0 -19\n-13 -33 49\n-30 0 28\n34 17 45\n-50 9 -27\n-50 0 0\n-37 0 0",
"output": "YES"
},
{
"input": "12\n3 28 -35\n-32 -44 -17\n9 -25 -6\n-42 -22 20\n-19 15 38\n-21 38 48\n-1 -37 -28\n-10 -13 -50\n-5 21 29\n34 28 50\n50 11 -49\n34 0 0",
"output": "YES"
},
{
"input": "37\n-64 -79 26\n-22 59 93\n-5 39 -12\n77 -9 76\n55 -86 57\n83 100 -97\n-70 94 84\n-14 46 -94\n26 72 35\n14 78 -62\n17 82 92\n-57 11 91\n23 15 92\n-80 -1 1\n12 39 18\n-23 -99 -75\n-34 50 19\n-39 84 -7\n45 -30 -39\n-60 49 37\n45 -16 -72\n33 -51 -56\n-48 28 5\n97 91 88\n45 -82 -11\n-21 -15 -90\n-53 73 -26\n-74 85 -90\n-40 23 38\n100 -13 49\n32 -100 -100\n0 -100 -70\n0 -100 0\n0 -100 0\n0 -100 0\n0 -100 0\n0 -37 0",
"output": "YES"
},
{
"input": "4\n68 3 100\n68 21 -100\n-100 -24 0\n-36 0 0",
"output": "YES"
},
{
"input": "33\n-1 -46 -12\n45 -16 -21\n-11 45 -21\n-60 -42 -93\n-22 -45 93\n37 96 85\n-76 26 83\n-4 9 55\n7 -52 -9\n66 8 -85\n-100 -54 11\n-29 59 74\n-24 12 2\n-56 81 85\n-92 69 -52\n-26 -97 91\n54 59 -51\n58 21 -57\n7 68 56\n-47 -20 -51\n-59 77 -13\n-85 27 91\n79 60 -56\n66 -80 5\n21 -99 42\n-31 -29 98\n66 93 76\n-49 45 61\n100 -100 -100\n100 -100 -100\n66 -75 -100\n0 0 -100\n0 0 -87",
"output": "YES"
},
{
"input": "3\n1 2 3\n3 2 1\n0 0 0",
"output": "NO"
},
{
"input": "2\n5 -23 12\n0 0 0",
"output": "NO"
},
{
"input": "1\n0 0 0",
"output": "YES"
},
{
"input": "1\n1 -2 0",
"output": "NO"
},
{
"input": "2\n-23 77 -86\n23 -77 86",
"output": "YES"
},
{
"input": "26\n86 7 20\n-57 -64 39\n-45 6 -93\n-44 -21 100\n-11 -49 21\n73 -71 -80\n-2 -89 56\n-65 -2 7\n5 14 84\n57 41 13\n-12 69 54\n40 -25 27\n-17 -59 0\n64 -91 -30\n-53 9 42\n-54 -8 14\n-35 82 27\n-48 -59 -80\n88 70 79\n94 57 97\n44 63 25\n84 -90 -40\n-100 100 -100\n-92 100 -100\n0 10 -100\n0 0 -82",
"output": "YES"
},
{
"input": "42\n11 27 92\n-18 -56 -57\n1 71 81\n33 -92 30\n82 83 49\n-87 -61 -1\n-49 45 49\n73 26 15\n-22 22 -77\n29 -93 87\n-68 44 -90\n-4 -84 20\n85 67 -6\n-39 26 77\n-28 -64 20\n65 -97 24\n-72 -39 51\n35 -75 -91\n39 -44 -8\n-25 -27 -57\n91 8 -46\n-98 -94 56\n94 -60 59\n-9 -95 18\n-53 -37 98\n-8 -94 -84\n-52 55 60\n15 -14 37\n65 -43 -25\n94 12 66\n-8 -19 -83\n29 81 -78\n-58 57 33\n24 86 -84\n-53 32 -88\n-14 7 3\n89 97 -53\n-5 -28 -91\n-100 100 -6\n-84 100 0\n0 100 0\n0 70 0",
"output": "YES"
},
{
"input": "3\n96 49 -12\n2 -66 28\n-98 17 -16",
"output": "YES"
},
{
"input": "5\n70 -46 86\n-100 94 24\n-27 63 -63\n57 -100 -47\n0 -11 0",
"output": "YES"
},
{
"input": "18\n-86 -28 70\n-31 -89 42\n31 -48 -55\n95 -17 -43\n24 -95 -85\n-21 -14 31\n68 -18 81\n13 31 60\n-15 28 99\n-42 15 9\n28 -61 -62\n-16 71 29\n-28 75 -48\n-77 -67 36\n-100 83 89\n100 100 -100\n57 34 -100\n0 0 -53",
"output": "YES"
},
{
"input": "44\n52 -54 -29\n-82 -5 -94\n-54 43 43\n91 16 71\n7 80 -91\n3 15 29\n-99 -6 -77\n-3 -77 -64\n73 67 34\n25 -10 -18\n-29 91 63\n-72 86 -16\n-68 85 -81\n-3 36 44\n-74 -14 -80\n34 -96 -97\n-76 -78 -33\n-24 44 -58\n98 12 77\n95 -63 -6\n-51 3 -90\n-92 -10 72\n7 3 -68\n57 -53 71\n29 57 -48\n35 -60 10\n79 -70 -61\n-20 77 55\n-86 -15 -35\n84 -88 -18\n100 -42 77\n-20 46 8\n-41 -43 -65\n38 -98 -23\n-100 65 45\n-7 -91 -63\n46 88 -85\n48 59 100\n0 0 100\n0 0 100\n0 0 100\n0 0 100\n0 0 100\n0 0 1",
"output": "YES"
},
{
"input": "18\n-14 -64 -91\n-8 -66 -86\n-23 92 -40\n6 -3 -53\n57 41 78\n-79 42 -22\n-88 -17 45\n4 -45 44\n83 -18 -25\n34 86 -92\n75 -30 12\n44 99 11\n-67 -13 72\n22 83 -56\n-37 71 72\n-9 -100 100\n0 -100 31\n0 -58 0",
"output": "YES"
},
{
"input": "23\n-70 37 78\n42 84 6\n28 -94 -24\n-49 76 95\n-67 18 84\n-53 78 -5\n65 -63 -64\n-66 -64 -69\n81 -93 95\n10 52 -79\n-89 -61 -64\n-64 -47 43\n-81 -35 55\n80 82 73\n-60 -81 -18\n49 -10 -19\n-58 70 12\n-24 -15 -93\n98 -93 -54\n-28 -75 11\n100 100 -63\n100 100 0\n56 34 0",
"output": "YES"
},
{
"input": "3\n0 2 -2\n1 -1 3\n-3 0 0",
"output": "NO"
}
] | 1,548,434,521
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 81
| 248
| 0
|
sum_1=0
f_1=0
sc_1=0
tr_1=0
n=int(input())
for i in range (n):
f,sc,tr=map(int,input().split())
f_1=f_1+f
sc_1=sc_1+sc
tr_1=tr_1+tr
if (f_1!=0) or (sc_1!=0) or (tr_1!=0):
print('NO')
if (f_1==0) and (sc_1==0) and (tr_1==0):
print('YES')
|
Title: Young Physicist
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
A guy named Vasya attends the final grade of a high school. One day Vasya decided to watch a match of his favorite hockey team. And, as the boy loves hockey very much, even more than physics, he forgot to do the homework. Specifically, he forgot to complete his physics tasks. Next day the teacher got very angry at Vasya and decided to teach him a lesson. He gave the lazy student a seemingly easy task: You are given an idle body in space and the forces that affect it. The body can be considered as a material point with coordinates (0; 0; 0). Vasya had only to answer whether it is in equilibrium. "Piece of cake" — thought Vasya, we need only to check if the sum of all vectors is equal to 0. So, Vasya began to solve the problem. But later it turned out that there can be lots and lots of these forces, and Vasya can not cope without your help. Help him. Write a program that determines whether a body is idle or is moving by the given vectors of forces.
Input Specification:
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100), then follow *n* lines containing three integers each: the *x**i* coordinate, the *y**i* coordinate and the *z**i* coordinate of the force vector, applied to the body (<=-<=100<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=100).
Output Specification:
Print the word "YES" if the body is in equilibrium, or the word "NO" if it is not.
Demo Input:
['3\n4 1 7\n-2 4 -1\n1 -5 -3\n', '3\n3 -1 7\n-5 2 -4\n2 -1 -3\n']
Demo Output:
['NO', 'YES']
Note:
none
|
```python
sum_1=0
f_1=0
sc_1=0
tr_1=0
n=int(input())
for i in range (n):
f,sc,tr=map(int,input().split())
f_1=f_1+f
sc_1=sc_1+sc
tr_1=tr_1+tr
if (f_1!=0) or (sc_1!=0) or (tr_1!=0):
print('NO')
if (f_1==0) and (sc_1==0) and (tr_1==0):
print('YES')
```
| 3.938
|
373
|
A
|
Collecting Beats is Fun
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
Cucumber boy is fan of Kyubeat, a famous music game.
Kyubeat has 16 panels for playing arranged in 4<=×<=4 table. When a panel lights up, he has to press that panel.
Each panel has a timing to press (the preffered time when a player should press it), and Cucumber boy is able to press at most *k* panels in a time with his one hand. Cucumber boy is trying to press all panels in perfect timing, that is he wants to press each panel exactly in its preffered time. If he cannot press the panels with his two hands in perfect timing, his challenge to press all the panels in perfect timing will fail.
You are given one scene of Kyubeat's panel from the music Cucumber boy is trying. Tell him is he able to press all the panels in perfect timing.
|
The first line contains a single integer *k* (1<=≤<=*k*<=≤<=5) — the number of panels Cucumber boy can press with his one hand.
Next 4 lines contain 4 characters each (digits from 1 to 9, or period) — table of panels. If a digit *i* was written on the panel, it means the boy has to press that panel in time *i*. If period was written on the panel, he doesn't have to press that panel.
|
Output "YES" (without quotes), if he is able to press all the panels in perfect timing. If not, output "NO" (without quotes).
|
[
"1\n.135\n1247\n3468\n5789\n",
"5\n..1.\n1111\n..1.\n..1.\n",
"1\n....\n12.1\n.2..\n.2..\n"
] |
[
"YES\n",
"YES\n",
"NO\n"
] |
In the third sample boy cannot press all panels in perfect timing. He can press all the panels in timing in time 1, but he cannot press the panels in time 2 in timing with his two hands.
| 500
|
[
{
"input": "1\n.135\n1247\n3468\n5789",
"output": "YES"
},
{
"input": "5\n..1.\n1111\n..1.\n..1.",
"output": "YES"
},
{
"input": "1\n....\n12.1\n.2..\n.2..",
"output": "NO"
},
{
"input": "1\n6981\n.527\n4163\n2345",
"output": "YES"
},
{
"input": "5\n9999\n9999\n9999\n9999",
"output": "NO"
},
{
"input": "2\n4444\n3333\n2222\n1111",
"output": "YES"
},
{
"input": "3\n2123\n1232\n2321\n3213",
"output": "NO"
},
{
"input": "2\n1...\n.1..\n..1.\n...1",
"output": "YES"
},
{
"input": "2\n1.1.\n.1.1\n2.2.\n.222",
"output": "NO"
},
{
"input": "1\n1..2\n.3.4\n567.\n.89.",
"output": "YES"
},
{
"input": "1\n1122\n3344\n5588\n6699",
"output": "YES"
},
{
"input": "4\n1111\n1221\n1221\n1111",
"output": "NO"
},
{
"input": "5\n3141\n5926\n5358\n9793",
"output": "YES"
},
{
"input": "5\n5454\n4343\n3232\n2121",
"output": "YES"
},
{
"input": "5\n1222\n2221\n2221\n1122",
"output": "NO"
},
{
"input": "1\n....\n5..5\n6..6\n7..7",
"output": "YES"
},
{
"input": "1\n9875\n8643\n7421\n531.",
"output": "YES"
},
{
"input": "1\n..1.\n..1.\n..1.\n..1.",
"output": "NO"
},
{
"input": "4\n4.4.\n4.4.\n4444\n..4.",
"output": "NO"
},
{
"input": "5\n4.4.\n4.4.\n4444\n..4.",
"output": "YES"
},
{
"input": "3\n1.1.\n.1.1\n1.1.\n.1.1",
"output": "NO"
},
{
"input": "2\n1131\n4412\n2569\n3478",
"output": "YES"
},
{
"input": "2\n8888\n8888\n8888\n8888",
"output": "NO"
}
] | 1,617,905,079
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 27
| 62
| 0
|
k=int(input())
l=[0]*10
for i in range(4):
for j in input():
if (j != '.'):
l[int(j)] += 1
for i in range(10):
if l[i] > k*2:
print("NO")
exit()
print("YES")
|
Title: Collecting Beats is Fun
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Cucumber boy is fan of Kyubeat, a famous music game.
Kyubeat has 16 panels for playing arranged in 4<=×<=4 table. When a panel lights up, he has to press that panel.
Each panel has a timing to press (the preffered time when a player should press it), and Cucumber boy is able to press at most *k* panels in a time with his one hand. Cucumber boy is trying to press all panels in perfect timing, that is he wants to press each panel exactly in its preffered time. If he cannot press the panels with his two hands in perfect timing, his challenge to press all the panels in perfect timing will fail.
You are given one scene of Kyubeat's panel from the music Cucumber boy is trying. Tell him is he able to press all the panels in perfect timing.
Input Specification:
The first line contains a single integer *k* (1<=≤<=*k*<=≤<=5) — the number of panels Cucumber boy can press with his one hand.
Next 4 lines contain 4 characters each (digits from 1 to 9, or period) — table of panels. If a digit *i* was written on the panel, it means the boy has to press that panel in time *i*. If period was written on the panel, he doesn't have to press that panel.
Output Specification:
Output "YES" (without quotes), if he is able to press all the panels in perfect timing. If not, output "NO" (without quotes).
Demo Input:
['1\n.135\n1247\n3468\n5789\n', '5\n..1.\n1111\n..1.\n..1.\n', '1\n....\n12.1\n.2..\n.2..\n']
Demo Output:
['YES\n', 'YES\n', 'NO\n']
Note:
In the third sample boy cannot press all panels in perfect timing. He can press all the panels in timing in time 1, but he cannot press the panels in time 2 in timing with his two hands.
|
```python
k=int(input())
l=[0]*10
for i in range(4):
for j in input():
if (j != '.'):
l[int(j)] += 1
for i in range(10):
if l[i] > k*2:
print("NO")
exit()
print("YES")
```
| 3
|
|
82
|
A
|
Double Cola
|
PROGRAMMING
| 1,100
|
[
"implementation",
"math"
] |
A. Double Cola
|
1
|
256
|
Sheldon, Leonard, Penny, Rajesh and Howard are in the queue for a "Double Cola" drink vending machine; there are no other people in the queue. The first one in the queue (Sheldon) buys a can, drinks it and doubles! The resulting two Sheldons go to the end of the queue. Then the next in the queue (Leonard) buys a can, drinks it and gets to the end of the queue as two Leonards, and so on. This process continues ad infinitum.
For example, Penny drinks the third can of cola and the queue will look like this: Rajesh, Howard, Sheldon, Sheldon, Leonard, Leonard, Penny, Penny.
Write a program that will print the name of a man who will drink the *n*-th can.
Note that in the very beginning the queue looks like that: Sheldon, Leonard, Penny, Rajesh, Howard. The first person is Sheldon.
|
The input data consist of a single integer *n* (1<=≤<=*n*<=≤<=109).
It is guaranteed that the pretests check the spelling of all the five names, that is, that they contain all the five possible answers.
|
Print the single line — the name of the person who drinks the *n*-th can of cola. The cans are numbered starting from 1. Please note that you should spell the names like this: "Sheldon", "Leonard", "Penny", "Rajesh", "Howard" (without the quotes). In that order precisely the friends are in the queue initially.
|
[
"1\n",
"6\n",
"1802\n"
] |
[
"Sheldon\n",
"Sheldon\n",
"Penny\n"
] |
none
| 500
|
[
{
"input": "1",
"output": "Sheldon"
},
{
"input": "6",
"output": "Sheldon"
},
{
"input": "1802",
"output": "Penny"
},
{
"input": "1",
"output": "Sheldon"
},
{
"input": "2",
"output": "Leonard"
},
{
"input": "3",
"output": "Penny"
},
{
"input": "4",
"output": "Rajesh"
},
{
"input": "5",
"output": "Howard"
},
{
"input": "10",
"output": "Penny"
},
{
"input": "534",
"output": "Rajesh"
},
{
"input": "5033",
"output": "Howard"
},
{
"input": "10010",
"output": "Howard"
},
{
"input": "500000000",
"output": "Penny"
},
{
"input": "63",
"output": "Rajesh"
},
{
"input": "841",
"output": "Leonard"
},
{
"input": "3667",
"output": "Penny"
},
{
"input": "38614",
"output": "Howard"
},
{
"input": "282798",
"output": "Rajesh"
},
{
"input": "9266286",
"output": "Rajesh"
},
{
"input": "27385966",
"output": "Leonard"
},
{
"input": "121580142",
"output": "Penny"
},
{
"input": "5",
"output": "Howard"
},
{
"input": "300",
"output": "Howard"
},
{
"input": "1745",
"output": "Leonard"
},
{
"input": "8302",
"output": "Rajesh"
},
{
"input": "184518",
"output": "Sheldon"
},
{
"input": "1154414",
"output": "Rajesh"
},
{
"input": "28643950",
"output": "Leonard"
},
{
"input": "159222638",
"output": "Howard"
},
{
"input": "24",
"output": "Penny"
},
{
"input": "505",
"output": "Penny"
},
{
"input": "4425",
"output": "Rajesh"
},
{
"input": "12079",
"output": "Sheldon"
},
{
"input": "469726",
"output": "Penny"
},
{
"input": "3961838",
"output": "Penny"
},
{
"input": "57710446",
"output": "Leonard"
},
{
"input": "80719470",
"output": "Howard"
},
{
"input": "1000000000",
"output": "Penny"
},
{
"input": "999999999",
"output": "Penny"
},
{
"input": "999999998",
"output": "Penny"
},
{
"input": "5",
"output": "Howard"
}
] | 1,621,583,396
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 41
| 62
| 0
|
n=int(input())
c=1
s = ["Sheldon", "Leonard", "Penny", "Rajesh", "Howard"]
while(c*5<n):
n=n-(c*5)
c*=2
n=n-1
n=n//c
print(s[n])
|
Title: Double Cola
Time Limit: 1 seconds
Memory Limit: 256 megabytes
Problem Description:
Sheldon, Leonard, Penny, Rajesh and Howard are in the queue for a "Double Cola" drink vending machine; there are no other people in the queue. The first one in the queue (Sheldon) buys a can, drinks it and doubles! The resulting two Sheldons go to the end of the queue. Then the next in the queue (Leonard) buys a can, drinks it and gets to the end of the queue as two Leonards, and so on. This process continues ad infinitum.
For example, Penny drinks the third can of cola and the queue will look like this: Rajesh, Howard, Sheldon, Sheldon, Leonard, Leonard, Penny, Penny.
Write a program that will print the name of a man who will drink the *n*-th can.
Note that in the very beginning the queue looks like that: Sheldon, Leonard, Penny, Rajesh, Howard. The first person is Sheldon.
Input Specification:
The input data consist of a single integer *n* (1<=≤<=*n*<=≤<=109).
It is guaranteed that the pretests check the spelling of all the five names, that is, that they contain all the five possible answers.
Output Specification:
Print the single line — the name of the person who drinks the *n*-th can of cola. The cans are numbered starting from 1. Please note that you should spell the names like this: "Sheldon", "Leonard", "Penny", "Rajesh", "Howard" (without the quotes). In that order precisely the friends are in the queue initially.
Demo Input:
['1\n', '6\n', '1802\n']
Demo Output:
['Sheldon\n', 'Sheldon\n', 'Penny\n']
Note:
none
|
```python
n=int(input())
c=1
s = ["Sheldon", "Leonard", "Penny", "Rajesh", "Howard"]
while(c*5<n):
n=n-(c*5)
c*=2
n=n-1
n=n//c
print(s[n])
```
| 3.969
|
950
|
A
|
Left-handers, Right-handers and Ambidexters
|
PROGRAMMING
| 800
|
[
"implementation",
"math"
] | null | null |
You are at a water bowling training. There are *l* people who play with their left hand, *r* people, who play with their right hand, and *a* ambidexters, who can play with left or right hand.
The coach decided to form a team of even number of players, exactly half of the players should play with their right hand, and exactly half of the players should play with their left hand. One player should use only on of his hands.
Ambidexters play as well with their right hand as with their left hand. In the team, an ambidexter can play with their left hand, or with their right hand.
Please find the maximum possible size of the team, where equal number of players use their left and right hands, respectively.
|
The only line contains three integers *l*, *r* and *a* (0<=≤<=*l*,<=*r*,<=*a*<=≤<=100) — the number of left-handers, the number of right-handers and the number of ambidexters at the training.
|
Print a single even integer — the maximum number of players in the team. It is possible that the team can only have zero number of players.
|
[
"1 4 2\n",
"5 5 5\n",
"0 2 0\n"
] |
[
"6\n",
"14\n",
"0\n"
] |
In the first example you can form a team of 6 players. You should take the only left-hander and two ambidexters to play with left hand, and three right-handers to play with right hand. The only person left can't be taken into the team.
In the second example you can form a team of 14 people. You have to take all five left-handers, all five right-handers, two ambidexters to play with left hand and two ambidexters to play with right hand.
| 500
|
[
{
"input": "1 4 2",
"output": "6"
},
{
"input": "5 5 5",
"output": "14"
},
{
"input": "0 2 0",
"output": "0"
},
{
"input": "30 70 34",
"output": "128"
},
{
"input": "89 32 24",
"output": "112"
},
{
"input": "89 44 77",
"output": "210"
},
{
"input": "0 0 0",
"output": "0"
},
{
"input": "100 100 100",
"output": "300"
},
{
"input": "1 1 1",
"output": "2"
},
{
"input": "30 70 35",
"output": "130"
},
{
"input": "89 44 76",
"output": "208"
},
{
"input": "0 100 100",
"output": "200"
},
{
"input": "100 0 100",
"output": "200"
},
{
"input": "100 1 100",
"output": "200"
},
{
"input": "1 100 100",
"output": "200"
},
{
"input": "100 100 0",
"output": "200"
},
{
"input": "100 100 1",
"output": "200"
},
{
"input": "1 2 1",
"output": "4"
},
{
"input": "0 0 100",
"output": "100"
},
{
"input": "0 100 0",
"output": "0"
},
{
"input": "100 0 0",
"output": "0"
},
{
"input": "10 8 7",
"output": "24"
},
{
"input": "45 47 16",
"output": "108"
},
{
"input": "59 43 100",
"output": "202"
},
{
"input": "34 1 30",
"output": "62"
},
{
"input": "14 81 1",
"output": "30"
},
{
"input": "53 96 94",
"output": "242"
},
{
"input": "62 81 75",
"output": "218"
},
{
"input": "21 71 97",
"output": "188"
},
{
"input": "49 82 73",
"output": "204"
},
{
"input": "88 19 29",
"output": "96"
},
{
"input": "89 4 62",
"output": "132"
},
{
"input": "58 3 65",
"output": "126"
},
{
"input": "27 86 11",
"output": "76"
},
{
"input": "35 19 80",
"output": "134"
},
{
"input": "4 86 74",
"output": "156"
},
{
"input": "32 61 89",
"output": "182"
},
{
"input": "68 60 98",
"output": "226"
},
{
"input": "37 89 34",
"output": "142"
},
{
"input": "92 9 28",
"output": "74"
},
{
"input": "79 58 98",
"output": "234"
},
{
"input": "35 44 88",
"output": "166"
},
{
"input": "16 24 19",
"output": "58"
},
{
"input": "74 71 75",
"output": "220"
},
{
"input": "83 86 99",
"output": "268"
},
{
"input": "97 73 15",
"output": "176"
},
{
"input": "77 76 73",
"output": "226"
},
{
"input": "48 85 55",
"output": "188"
},
{
"input": "1 2 2",
"output": "4"
},
{
"input": "2 2 2",
"output": "6"
},
{
"input": "2 1 2",
"output": "4"
},
{
"input": "2 2 1",
"output": "4"
},
{
"input": "3 2 1",
"output": "6"
},
{
"input": "1 2 3",
"output": "6"
},
{
"input": "1 3 2",
"output": "6"
},
{
"input": "2 1 3",
"output": "6"
},
{
"input": "2 3 1",
"output": "6"
},
{
"input": "3 1 2",
"output": "6"
},
{
"input": "99 99 99",
"output": "296"
},
{
"input": "99 99 100",
"output": "298"
},
{
"input": "99 100 99",
"output": "298"
},
{
"input": "99 100 100",
"output": "298"
},
{
"input": "100 99 99",
"output": "298"
},
{
"input": "100 99 100",
"output": "298"
},
{
"input": "100 100 99",
"output": "298"
},
{
"input": "89 32 23",
"output": "110"
},
{
"input": "4 5 0",
"output": "8"
},
{
"input": "3 0 3",
"output": "6"
},
{
"input": "0 0 2",
"output": "2"
},
{
"input": "97 97 0",
"output": "194"
},
{
"input": "1 4 0",
"output": "2"
},
{
"input": "5 2 0",
"output": "4"
},
{
"input": "0 5 10",
"output": "14"
},
{
"input": "0 1 2",
"output": "2"
},
{
"input": "5 2 3",
"output": "10"
},
{
"input": "5 5 0",
"output": "10"
},
{
"input": "0 0 10",
"output": "10"
},
{
"input": "0 1 1",
"output": "2"
},
{
"input": "0 0 1",
"output": "0"
}
] | 1,595,356,392
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 79
| 109
| 6,656,000
|
from math import floor
import sys
l, r, a = sys.stdin.readline().split()
l, r, a = int(l), int(r), int(a)
min = min(l, r)
max = max(l, r)
if min+a <= max:
print (2*(min+a))
else:
print (((min+a+max)//2)*2)
|
Title: Left-handers, Right-handers and Ambidexters
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are at a water bowling training. There are *l* people who play with their left hand, *r* people, who play with their right hand, and *a* ambidexters, who can play with left or right hand.
The coach decided to form a team of even number of players, exactly half of the players should play with their right hand, and exactly half of the players should play with their left hand. One player should use only on of his hands.
Ambidexters play as well with their right hand as with their left hand. In the team, an ambidexter can play with their left hand, or with their right hand.
Please find the maximum possible size of the team, where equal number of players use their left and right hands, respectively.
Input Specification:
The only line contains three integers *l*, *r* and *a* (0<=≤<=*l*,<=*r*,<=*a*<=≤<=100) — the number of left-handers, the number of right-handers and the number of ambidexters at the training.
Output Specification:
Print a single even integer — the maximum number of players in the team. It is possible that the team can only have zero number of players.
Demo Input:
['1 4 2\n', '5 5 5\n', '0 2 0\n']
Demo Output:
['6\n', '14\n', '0\n']
Note:
In the first example you can form a team of 6 players. You should take the only left-hander and two ambidexters to play with left hand, and three right-handers to play with right hand. The only person left can't be taken into the team.
In the second example you can form a team of 14 people. You have to take all five left-handers, all five right-handers, two ambidexters to play with left hand and two ambidexters to play with right hand.
|
```python
from math import floor
import sys
l, r, a = sys.stdin.readline().split()
l, r, a = int(l), int(r), int(a)
min = min(l, r)
max = max(l, r)
if min+a <= max:
print (2*(min+a))
else:
print (((min+a+max)//2)*2)
```
| 3
|
|
133
|
A
|
HQ9+
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
HQ9+ is a joke programming language which has only four one-character instructions:
- "H" prints "Hello, World!",- "Q" prints the source code of the program itself,- "9" prints the lyrics of "99 Bottles of Beer" song, - "+" increments the value stored in the internal accumulator.
Instructions "H" and "Q" are case-sensitive and must be uppercase. The characters of the program which are not instructions are ignored.
You are given a program written in HQ9+. You have to figure out whether executing this program will produce any output.
|
The input will consist of a single line *p* which will give a program in HQ9+. String *p* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *p* will be between 33 (exclamation mark) and 126 (tilde), inclusive.
|
Output "YES", if executing the program will produce any output, and "NO" otherwise.
|
[
"Hi!\n",
"Codeforces\n"
] |
[
"YES\n",
"NO\n"
] |
In the first case the program contains only one instruction — "H", which prints "Hello, World!".
In the second case none of the program characters are language instructions.
| 500
|
[
{
"input": "Hi!",
"output": "YES"
},
{
"input": "Codeforces",
"output": "NO"
},
{
"input": "a+b=c",
"output": "NO"
},
{
"input": "hq-lowercase",
"output": "NO"
},
{
"input": "Q",
"output": "YES"
},
{
"input": "9",
"output": "YES"
},
{
"input": "H",
"output": "YES"
},
{
"input": "+",
"output": "NO"
},
{
"input": "~",
"output": "NO"
},
{
"input": "dEHsbM'gS[\\brZ_dpjXw8f?L[4E\"s4Zc9*(,j:>p$}m7HD[_9nOWQ\\uvq2mHWR",
"output": "YES"
},
{
"input": "tt6l=RHOfStm.;Qd$-}zDes*E,.F7qn5-b%HC",
"output": "YES"
},
{
"input": "@F%K2=%RyL/",
"output": "NO"
},
{
"input": "juq)k(FT.^G=G\\zcqnO\"uJIE1_]KFH9S=1c\"mJ;F9F)%>&.WOdp09+k`Yc6}\"6xw,Aos:M\\_^^:xBb[CcsHm?J",
"output": "YES"
},
{
"input": "6G_\"Fq#<AWyHG=Rci1t%#Jc#x<Fpg'N@t%F=``YO7\\Zd;6PkMe<#91YgzTC)",
"output": "YES"
},
{
"input": "Fvg_~wC>SO4lF}*c`Q;mII9E{4.QodbqN]C",
"output": "YES"
},
{
"input": "p-UXsbd&f",
"output": "NO"
},
{
"input": "<]D7NMA)yZe=`?RbP5lsa.l_Mg^V:\"-0x+$3c,q&L%18Ku<HcA\\s!^OQblk^x{35S'>yz8cKgVHWZ]kV0>_",
"output": "YES"
},
{
"input": "f.20)8b+.R}Gy!DbHU3v(.(=Q^`z[_BaQ}eO=C1IK;b2GkD\\{\\Bf\"!#qh]",
"output": "YES"
},
{
"input": "}do5RU<(w<q[\"-NR)IAH_HyiD{",
"output": "YES"
},
{
"input": "Iy^.,Aw*,5+f;l@Q;jLK'G5H-r1Pfmx?ei~`CjMmUe{K:lS9cu4ay8rqRh-W?Gqv!e-j*U)!Mzn{E8B6%~aSZ~iQ_QwlC9_cX(o8",
"output": "YES"
},
{
"input": "sKLje,:q>-D,;NvQ3,qN3-N&tPx0nL/,>Ca|z\"k2S{NF7btLa3_TyXG4XZ:`(t&\"'^M|@qObZxv",
"output": "YES"
},
{
"input": "%z:c@1ZsQ@\\6U/NQ+M9R>,$bwG`U1+C\\18^:S},;kw!&4r|z`",
"output": "YES"
},
{
"input": "OKBB5z7ud81[Tn@P\"nDUd,>@",
"output": "NO"
},
{
"input": "y{0;neX]w0IenPvPx0iXp+X|IzLZZaRzBJ>q~LhMhD$x-^GDwl;,a'<bAqH8QrFwbK@oi?I'W.bZ]MlIQ/x(0YzbTH^l.)]0Bv",
"output": "YES"
},
{
"input": "EL|xIP5_+Caon1hPpQ0[8+r@LX4;b?gMy>;/WH)pf@Ur*TiXu*e}b-*%acUA~A?>MDz#!\\Uh",
"output": "YES"
},
{
"input": "UbkW=UVb>;z6)p@Phr;^Dn.|5O{_i||:Rv|KJ_ay~V(S&Jp",
"output": "NO"
},
{
"input": "!3YPv@2JQ44@)R2O_4`GO",
"output": "YES"
},
{
"input": "Kba/Q,SL~FMd)3hOWU'Jum{9\"$Ld4:GW}D]%tr@G{hpG:PV5-c'VIZ~m/6|3I?_4*1luKnOp`%p|0H{[|Y1A~4-ZdX,Rw2[\\",
"output": "YES"
},
{
"input": "NRN*=v>;oU7[acMIJn*n^bWm!cm3#E7Efr>{g-8bl\"DN4~_=f?[T;~Fq#&)aXq%</GcTJD^e$@Extm[e\"C)q_L",
"output": "NO"
},
{
"input": "y#<fv{_=$MP!{D%I\\1OqjaqKh[pqE$KvYL<9@*V'j8uH0/gQdA'G;&y4Cv6&",
"output": "YES"
},
{
"input": "+SE_Pg<?7Fh,z&uITQut2a-mk8X8La`c2A}",
"output": "YES"
},
{
"input": "Uh3>ER](J",
"output": "NO"
},
{
"input": "!:!{~=9*\\P;Z6F?HC5GadFz)>k*=u|+\"Cm]ICTmB!`L{&oS/z6b~#Snbp/^\\Q>XWU-vY+/dP.7S=-#&whS@,",
"output": "YES"
},
{
"input": "KimtYBZp+ISeO(uH;UldoE6eAcp|9u?SzGZd6j-e}[}u#e[Cx8.qgY]$2!",
"output": "YES"
},
{
"input": "[:[SN-{r>[l+OggH3v3g{EPC*@YBATT@",
"output": "YES"
},
{
"input": "'jdL(vX",
"output": "NO"
},
{
"input": "Q;R+aay]cL?Zh*uG\"YcmO*@Dts*Gjp}D~M7Z96+<4?9I3aH~0qNdO(RmyRy=ci,s8qD_kwj;QHFzD|5,5",
"output": "YES"
},
{
"input": "{Q@#<LU_v^qdh%gGxz*pu)Y\"]k-l-N30WAxvp2IE3:jD0Wi4H/xWPH&s",
"output": "YES"
},
{
"input": "~@Gb(S&N$mBuBUMAky-z^{5VwLNTzYg|ZUZncL@ahS?K*As<$iNUARM3r43J'jJB)$ujfPAq\"G<S9flGyakZg!2Z.-NJ|2{F>]",
"output": "YES"
},
{
"input": "Jp5Aa>aP6fZ!\\6%A}<S}j{O4`C6y$8|i3IW,WHy&\"ioE&7zP\"'xHAY;:x%@SnS]Mr{R|})gU",
"output": "YES"
},
{
"input": "ZA#:U)$RI^sE\\vuAt]x\"2zipI!}YEu2<j$:H0_9/~eB?#->",
"output": "YES"
},
{
"input": "&ppw0._:\\p-PuWM@l}%%=",
"output": "NO"
},
{
"input": "P(^pix\"=oiEZu8?@d@J(I`Xp5TN^T3\\Z7P5\"ZrvZ{2Fwz3g-8`U!)(1$a<g+9Q|COhDoH;HwFY02Pa|ZGp$/WZBR=>6Jg!yr",
"output": "YES"
},
{
"input": "`WfODc\\?#ax~1xu@[ao+o_rN|L7%v,p,nDv>3+6cy.]q3)+A6b!q*Hc+#.t4f~vhUa~$^q",
"output": "YES"
},
{
"input": ",)TH9N}'6t2+0Yg?S#6/{_.,!)9d}h'wG|sY&'Ul4D0l0",
"output": "YES"
},
{
"input": "VXB&r9Z)IlKOJ:??KDA",
"output": "YES"
},
{
"input": "\")1cL>{o\\dcYJzu?CefyN^bGRviOH&P7rJS3PT4:0V3F)%\\}L=AJouYsj_>j2|7^1NWu*%NbOP>ngv-ls<;b-4Sd3Na0R",
"output": "YES"
},
{
"input": "2Y}\\A)>row{~c[g>:'.|ZC8%UTQ/jcdhK%6O)QRC.kd@%y}LJYk=V{G5pQK/yKJ%{G3C",
"output": "YES"
},
{
"input": "O.&=qt(`z(",
"output": "NO"
},
{
"input": "_^r6fyIc/~~;>l%9?aVEi7-{=,[<aMiB'-scSg$$|\"jAzY0N>QkHHGBZj2c\"=fhRlWd5;5K|GgU?7h]!;wl@",
"output": "YES"
},
{
"input": "+/`sAd&eB29E=Nu87${.u6GY@$^a$,}s^!p!F}B-z8<<wORb<S7;HM1a,gp",
"output": "YES"
},
{
"input": "U_ilyOGMT+QiW/M8/D(1=6a7)_FA,h4`8",
"output": "YES"
},
{
"input": "!0WKT:$O",
"output": "NO"
},
{
"input": "1EE*I%EQz6$~pPu7|(r7nyPQt4uGU@]~H'4uII?b1_Wn)K?ZRHrr0z&Kr;}aO3<mN=3:{}QgPxI|Ncm4#)",
"output": "YES"
},
{
"input": "[u3\"$+!:/.<Dp1M7tH}:zxjt],^kv}qP;y12\"`^'/u*h%AFmPJ>e1#Yly",
"output": "YES"
},
{
"input": "'F!_]tB<A&UO+p?7liE>(x&RFgG2~\\(",
"output": "NO"
},
{
"input": "Qv)X8",
"output": "YES"
},
{
"input": "aGv7,J@&g1(}E3g6[LuDZwZl2<v7IwQA%\"R(?ouBD>_=y\"3Kf%^>vON<a^T\\G^ootgE@whWmZo=[ex|F",
"output": "YES"
},
{
"input": "e{}2vQ+/r@p0}cLKNe4MCk",
"output": "YES"
},
{
"input": "mzbmweyydiadtlcouegmdbyfwurpwbpuvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnkH",
"output": "YES"
},
{
"input": "Qzbmweyydiadtlcouegmdbyfwurpwbpuvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnky",
"output": "YES"
},
{
"input": "mzbmweyydiadtlcouegmdbyfwurpwb9uvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnky",
"output": "YES"
},
{
"input": "1H1",
"output": "YES"
},
{
"input": "+Q",
"output": "YES"
},
{
"input": "1ab",
"output": "NO"
},
{
"input": "!",
"output": "NO"
},
{
"input": "0+",
"output": "NO"
},
{
"input": "+H",
"output": "YES"
},
{
"input": "cH",
"output": "YES"
},
{
"input": "+8",
"output": "NO"
},
{
"input": "8+",
"output": "NO"
},
{
"input": "++++++++++++++++++++++++++",
"output": "NO"
},
{
"input": "(+)",
"output": "NO"
},
{
"input": "H+",
"output": "YES"
},
{
"input": "a!",
"output": "NO"
},
{
"input": "++++++++++++++",
"output": "NO"
},
{
"input": "+++++++++++++++++++++++++++++++++++++++++++++++++++++++++",
"output": "NO"
},
{
"input": "8",
"output": "NO"
},
{
"input": "3",
"output": "NO"
},
{
"input": "HQ9",
"output": "YES"
},
{
"input": "+++H",
"output": "YES"
},
{
"input": "++++++++++",
"output": "NO"
},
{
"input": "HHHHHHH",
"output": "YES"
},
{
"input": "abacabaH",
"output": "YES"
},
{
"input": "+G",
"output": "NO"
}
] | 1,693,499,664
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 85
| 92
| 0
|
a=input()
for i in range(len(a)):
if a[i]=='H' or a[i]=='9' or a[i]=='Q':
print("YES")
quit()
print("NO")
|
Title: HQ9+
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
HQ9+ is a joke programming language which has only four one-character instructions:
- "H" prints "Hello, World!",- "Q" prints the source code of the program itself,- "9" prints the lyrics of "99 Bottles of Beer" song, - "+" increments the value stored in the internal accumulator.
Instructions "H" and "Q" are case-sensitive and must be uppercase. The characters of the program which are not instructions are ignored.
You are given a program written in HQ9+. You have to figure out whether executing this program will produce any output.
Input Specification:
The input will consist of a single line *p* which will give a program in HQ9+. String *p* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *p* will be between 33 (exclamation mark) and 126 (tilde), inclusive.
Output Specification:
Output "YES", if executing the program will produce any output, and "NO" otherwise.
Demo Input:
['Hi!\n', 'Codeforces\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In the first case the program contains only one instruction — "H", which prints "Hello, World!".
In the second case none of the program characters are language instructions.
|
```python
a=input()
for i in range(len(a)):
if a[i]=='H' or a[i]=='9' or a[i]=='Q':
print("YES")
quit()
print("NO")
```
| 3
|
|
305
|
E
|
Playing with String
|
PROGRAMMING
| 2,300
|
[
"games"
] | null | null |
Two people play the following string game. Initially the players have got some string *s*. The players move in turns, the player who cannot make a move loses.
Before the game began, the string is written on a piece of paper, one letter per cell.
A player's move is the sequence of actions:
1. The player chooses one of the available pieces of paper with some string written on it. Let's denote it is *t*. Note that initially, only one piece of paper is available. 1. The player chooses in the string *t*<==<=*t*1*t*2... *t*|*t*| character in position *i* (1<=≤<=*i*<=≤<=|*t*|) such that for some positive integer *l* (0<=<<=*i*<=-<=*l*; *i*<=+<=*l*<=≤<=|*t*|) the following equations hold: *t**i*<=-<=1<==<=*t**i*<=+<=1, *t**i*<=-<=2<==<=*t**i*<=+<=2, ..., *t**i*<=-<=*l*<==<=*t**i*<=+<=*l*. 1. Player cuts the cell with the chosen character. As a result of the operation, he gets three new pieces of paper, the first one will contain string *t*1*t*2... *t**i*<=-<=1, the second one will contain a string consisting of a single character *t**i*, the third one contains string *t**i*<=+<=1*t**i*<=+<=2... *t*|*t*|.
Your task is to determine the winner provided that both players play optimally well. If the first player wins, find the position of character that is optimal to cut in his first move. If there are multiple positions, print the minimal possible one.
|
The first line contains string *s* (1<=≤<=|*s*|<=≤<=5000). It is guaranteed that string *s* only contains lowercase English letters.
|
If the second player wins, print in the single line "Second" (without the quotes). Otherwise, print in the first line "First" (without the quotes), and in the second line print the minimal possible winning move — integer *i* (1<=≤<=*i*<=≤<=|*s*|).
|
[
"abacaba\n",
"abcde\n"
] |
[
"First\n2\n",
"Second\n"
] |
In the first sample the first player has multiple winning moves. But the minimum one is to cut the character in position 2.
In the second sample the first player has no available moves.
| 2,500
|
[
{
"input": "abacaba",
"output": "First\n2"
},
{
"input": "abcde",
"output": "Second"
},
{
"input": "aaaaa",
"output": "First\n3"
},
{
"input": "aaabbbbbbbbabaaabbaabbbbabbabaabaabbbaabbbbbbabbbabaabaaabaaaabbaaabbbbaabbbaaabababbbbabbabbabaaaaabababbbaabbbaabababaaabababbaaaaaaaabbbbabbabbbababbababbbaabbbbbbbabaababaaabababbabbaabbbbbaabaabaabbbabbabbbbabaabbabaaaabbbbaabaaabbaabbabbaaabbbbaaaaaaabbbbbbbbbbabaaabaabababaabababbbbbbbabaababababbbaababaaaabbaababaaabbaaaabbabbabaaaaaabbabbbbbababbabbabbaaababbbaaababbb",
"output": "Second"
},
{
"input": "abbabbaaababbbbbbabbbbaabbabaababaababbbabbbaaaaaabbabbabbaabbbbaaaabbabaababbbabbaabaabbbaabaaaabbbbbabbbbbaababbabaabaababbbbbbbaaaababbabbaababbabaabbbbbabbbbaabaaabbbababaaabbbbabaaaabbbbbbbbbabbbbababababbbbaabbababaaabbabbaaaabaaabbbbabbbaaaabbabbaabaaaabaaaaabaaabbbbaaabababaaabbbaabbababbaaabbbbaabaabbbaaaaaabbaaabbaabbbaaabbbbbabbbbaabababbbababaaabbbaabbbbbaababaaabaabbbbba",
"output": "First\n4"
},
{
"input": "hwlyeasmdahtbvvguqxrbkzzbladwolhqwnelgatnbcwxpcbzdsuriybdopjiljwyjldjvbcgwdlyrrsbpjkkembkxhsqraqzbtartvbptgsbcibfxqgiosreccmvkfvcxvxxejxtthxnaqhkmzihkjcehlubhdsyhpacwfqetifotriilokxgrjsfpwemrgiyjsbxpvvfiycbxzwcuhivdxvjgyaandwncxqkkrvhfwdnhxnbzilfpkbchsjrer",
"output": "Second"
},
{
"input": "gggggggggggggg",
"output": "First\n5"
},
{
"input": "tttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttttiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogog",
"output": "First\n6"
}
] | 1,606,740,414
| 2,147,483,647
|
Python 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 6
| 2,000
| 307,200
|
U = input()
memo = {}
DP = [0]*(len(U)+1)
DP[0] = 0
for j in range(1, len(U) + 1):
s = set()
for i in range(j):
s.add(DP[max(0, i - 1)] ^ DP[max(0, j - i - 2)])
mex = 0
while mex in s:
mex += 1
DP[j] = mex
memo2 = {}
def Grundy(S):
"""
Basically we transform the game.
From a game where we can pick only center of palindrom to a game with several pile where we can pick anything (but it removes adjacent stone)
In this new game, only the remaining size matters (since we can pick anywhere)
"""
if S in memo2: return memo2[S]
total = 0
consec = 0
for i in range(1, len(S) - 1):
if S[i - 1] == S[i + 1]:
consec += 1
else:
total ^= DP[consec]
consec = 0
total ^= DP[consec]
memo2[S] = total
return total
import sys
sys.setrecursionlimit(3000)
if (Grundy(U) != 0):
#print(Grundy(U))
for i in range(1, len(U) - 1):
if U[i - 1] == U[i + 1]:
if ((Grundy(U[:i]) ^ Grundy(U[i + 1:])) == 0):
print("First")
print(i + 1)
break
else:
print("Second")
|
Title: Playing with String
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Two people play the following string game. Initially the players have got some string *s*. The players move in turns, the player who cannot make a move loses.
Before the game began, the string is written on a piece of paper, one letter per cell.
A player's move is the sequence of actions:
1. The player chooses one of the available pieces of paper with some string written on it. Let's denote it is *t*. Note that initially, only one piece of paper is available. 1. The player chooses in the string *t*<==<=*t*1*t*2... *t*|*t*| character in position *i* (1<=≤<=*i*<=≤<=|*t*|) such that for some positive integer *l* (0<=<<=*i*<=-<=*l*; *i*<=+<=*l*<=≤<=|*t*|) the following equations hold: *t**i*<=-<=1<==<=*t**i*<=+<=1, *t**i*<=-<=2<==<=*t**i*<=+<=2, ..., *t**i*<=-<=*l*<==<=*t**i*<=+<=*l*. 1. Player cuts the cell with the chosen character. As a result of the operation, he gets three new pieces of paper, the first one will contain string *t*1*t*2... *t**i*<=-<=1, the second one will contain a string consisting of a single character *t**i*, the third one contains string *t**i*<=+<=1*t**i*<=+<=2... *t*|*t*|.
Your task is to determine the winner provided that both players play optimally well. If the first player wins, find the position of character that is optimal to cut in his first move. If there are multiple positions, print the minimal possible one.
Input Specification:
The first line contains string *s* (1<=≤<=|*s*|<=≤<=5000). It is guaranteed that string *s* only contains lowercase English letters.
Output Specification:
If the second player wins, print in the single line "Second" (without the quotes). Otherwise, print in the first line "First" (without the quotes), and in the second line print the minimal possible winning move — integer *i* (1<=≤<=*i*<=≤<=|*s*|).
Demo Input:
['abacaba\n', 'abcde\n']
Demo Output:
['First\n2\n', 'Second\n']
Note:
In the first sample the first player has multiple winning moves. But the minimum one is to cut the character in position 2.
In the second sample the first player has no available moves.
|
```python
U = input()
memo = {}
DP = [0]*(len(U)+1)
DP[0] = 0
for j in range(1, len(U) + 1):
s = set()
for i in range(j):
s.add(DP[max(0, i - 1)] ^ DP[max(0, j - i - 2)])
mex = 0
while mex in s:
mex += 1
DP[j] = mex
memo2 = {}
def Grundy(S):
"""
Basically we transform the game.
From a game where we can pick only center of palindrom to a game with several pile where we can pick anything (but it removes adjacent stone)
In this new game, only the remaining size matters (since we can pick anywhere)
"""
if S in memo2: return memo2[S]
total = 0
consec = 0
for i in range(1, len(S) - 1):
if S[i - 1] == S[i + 1]:
consec += 1
else:
total ^= DP[consec]
consec = 0
total ^= DP[consec]
memo2[S] = total
return total
import sys
sys.setrecursionlimit(3000)
if (Grundy(U) != 0):
#print(Grundy(U))
for i in range(1, len(U) - 1):
if U[i - 1] == U[i + 1]:
if ((Grundy(U[:i]) ^ Grundy(U[i + 1:])) == 0):
print("First")
print(i + 1)
break
else:
print("Second")
```
| 0
|
|
228
|
A
|
Is your horseshoe on the other hoof?
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Valera the Horse is going to the party with friends. He has been following the fashion trends for a while, and he knows that it is very popular to wear all horseshoes of different color. Valera has got four horseshoes left from the last year, but maybe some of them have the same color. In this case he needs to go to the store and buy some few more horseshoes, not to lose face in front of his stylish comrades.
Fortunately, the store sells horseshoes of all colors under the sun and Valera has enough money to buy any four of them. However, in order to save the money, he would like to spend as little money as possible, so you need to help Valera and determine what is the minimum number of horseshoes he needs to buy to wear four horseshoes of different colors to a party.
|
The first line contains four space-separated integers *s*1,<=*s*2,<=*s*3,<=*s*4 (1<=≤<=*s*1,<=*s*2,<=*s*3,<=*s*4<=≤<=109) — the colors of horseshoes Valera has.
Consider all possible colors indexed with integers.
|
Print a single integer — the minimum number of horseshoes Valera needs to buy.
|
[
"1 7 3 3\n",
"7 7 7 7\n"
] |
[
"1\n",
"3\n"
] |
none
| 500
|
[
{
"input": "1 7 3 3",
"output": "1"
},
{
"input": "7 7 7 7",
"output": "3"
},
{
"input": "81170865 673572653 756938629 995577259",
"output": "0"
},
{
"input": "3491663 217797045 522540872 715355328",
"output": "0"
},
{
"input": "251590420 586975278 916631563 586975278",
"output": "1"
},
{
"input": "259504825 377489979 588153796 377489979",
"output": "1"
},
{
"input": "652588203 931100304 931100304 652588203",
"output": "2"
},
{
"input": "391958720 651507265 391958720 651507265",
"output": "2"
},
{
"input": "90793237 90793237 90793237 90793237",
"output": "3"
},
{
"input": "551651653 551651653 551651653 551651653",
"output": "3"
},
{
"input": "156630260 609654355 668943582 973622757",
"output": "0"
},
{
"input": "17061017 110313588 434481173 796661222",
"output": "0"
},
{
"input": "24975422 256716298 337790533 690960249",
"output": "0"
},
{
"input": "255635360 732742923 798648949 883146723",
"output": "0"
},
{
"input": "133315691 265159773 734556507 265159773",
"output": "1"
},
{
"input": "28442865 741657755 978106882 978106882",
"output": "1"
},
{
"input": "131245479 174845575 497483467 131245479",
"output": "1"
},
{
"input": "139159884 616215581 958341883 616215581",
"output": "1"
},
{
"input": "147784432 947653080 947653080 947653080",
"output": "2"
},
{
"input": "94055790 756126496 756126496 94055790",
"output": "2"
},
{
"input": "240458500 511952208 240458500 511952208",
"output": "2"
},
{
"input": "681828506 972810624 972810624 681828506",
"output": "2"
},
{
"input": "454961014 454961014 454961014 454961014",
"output": "3"
},
{
"input": "915819430 915819430 915819430 915819430",
"output": "3"
},
{
"input": "671645142 671645142 671645142 671645142",
"output": "3"
},
{
"input": "132503558 132503558 132503558 132503558",
"output": "3"
},
{
"input": "5 5 999999 6",
"output": "1"
},
{
"input": "1 1 2 5",
"output": "1"
},
{
"input": "2 1 2 3",
"output": "1"
},
{
"input": "1 1 3 5",
"output": "1"
},
{
"input": "1 1 3 3",
"output": "2"
},
{
"input": "2 2 2 1",
"output": "2"
},
{
"input": "3 1 1 1",
"output": "2"
},
{
"input": "1 2 2 2",
"output": "2"
}
] | 1,688,980,415
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 0
| 60
| 0
|
b=list(map(int,input().split()))
d=0
print(b)
for i in range (len(b)):
if i<len(b)-1:
if b[i] != b[i+1]:
d+=0
else:
d+=1
print(d)
|
Title: Is your horseshoe on the other hoof?
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Valera the Horse is going to the party with friends. He has been following the fashion trends for a while, and he knows that it is very popular to wear all horseshoes of different color. Valera has got four horseshoes left from the last year, but maybe some of them have the same color. In this case he needs to go to the store and buy some few more horseshoes, not to lose face in front of his stylish comrades.
Fortunately, the store sells horseshoes of all colors under the sun and Valera has enough money to buy any four of them. However, in order to save the money, he would like to spend as little money as possible, so you need to help Valera and determine what is the minimum number of horseshoes he needs to buy to wear four horseshoes of different colors to a party.
Input Specification:
The first line contains four space-separated integers *s*1,<=*s*2,<=*s*3,<=*s*4 (1<=≤<=*s*1,<=*s*2,<=*s*3,<=*s*4<=≤<=109) — the colors of horseshoes Valera has.
Consider all possible colors indexed with integers.
Output Specification:
Print a single integer — the minimum number of horseshoes Valera needs to buy.
Demo Input:
['1 7 3 3\n', '7 7 7 7\n']
Demo Output:
['1\n', '3\n']
Note:
none
|
```python
b=list(map(int,input().split()))
d=0
print(b)
for i in range (len(b)):
if i<len(b)-1:
if b[i] != b[i+1]:
d+=0
else:
d+=1
print(d)
```
| 0
|
|
9
|
A
|
Die Roll
|
PROGRAMMING
| 800
|
[
"math",
"probabilities"
] |
A. Die Roll
|
1
|
64
|
Yakko, Wakko and Dot, world-famous animaniacs, decided to rest from acting in cartoons, and take a leave to travel a bit. Yakko dreamt to go to Pennsylvania, his Motherland and the Motherland of his ancestors. Wakko thought about Tasmania, its beaches, sun and sea. Dot chose Transylvania as the most mysterious and unpredictable place.
But to their great regret, the leave turned to be very short, so it will be enough to visit one of the three above named places. That's why Yakko, as the cleverest, came up with a truly genius idea: let each of the three roll an ordinary six-sided die, and the one with the highest amount of points will be the winner, and will take the other two to the place of his/her dreams.
Yakko thrown a die and got Y points, Wakko — W points. It was Dot's turn. But she didn't hurry. Dot wanted to know for sure what were her chances to visit Transylvania.
It is known that Yakko and Wakko are true gentlemen, that's why if they have the same amount of points with Dot, they will let Dot win.
|
The only line of the input file contains two natural numbers Y and W — the results of Yakko's and Wakko's die rolls.
|
Output the required probability in the form of irreducible fraction in format «A/B», where A — the numerator, and B — the denominator. If the required probability equals to zero, output «0/1». If the required probability equals to 1, output «1/1».
|
[
"4 2\n"
] |
[
"1/2\n"
] |
Dot will go to Transylvania, if she is lucky to roll 4, 5 or 6 points.
| 0
|
[
{
"input": "4 2",
"output": "1/2"
},
{
"input": "1 1",
"output": "1/1"
},
{
"input": "1 2",
"output": "5/6"
},
{
"input": "1 3",
"output": "2/3"
},
{
"input": "1 4",
"output": "1/2"
},
{
"input": "1 5",
"output": "1/3"
},
{
"input": "1 6",
"output": "1/6"
},
{
"input": "2 1",
"output": "5/6"
},
{
"input": "2 2",
"output": "5/6"
},
{
"input": "2 3",
"output": "2/3"
},
{
"input": "2 4",
"output": "1/2"
},
{
"input": "2 5",
"output": "1/3"
},
{
"input": "2 6",
"output": "1/6"
},
{
"input": "3 1",
"output": "2/3"
},
{
"input": "3 2",
"output": "2/3"
},
{
"input": "3 3",
"output": "2/3"
},
{
"input": "3 4",
"output": "1/2"
},
{
"input": "3 5",
"output": "1/3"
},
{
"input": "3 6",
"output": "1/6"
},
{
"input": "4 1",
"output": "1/2"
},
{
"input": "4 3",
"output": "1/2"
},
{
"input": "4 4",
"output": "1/2"
},
{
"input": "4 5",
"output": "1/3"
},
{
"input": "4 6",
"output": "1/6"
},
{
"input": "5 1",
"output": "1/3"
},
{
"input": "5 2",
"output": "1/3"
},
{
"input": "5 3",
"output": "1/3"
},
{
"input": "5 4",
"output": "1/3"
},
{
"input": "5 5",
"output": "1/3"
},
{
"input": "5 6",
"output": "1/6"
},
{
"input": "6 1",
"output": "1/6"
},
{
"input": "6 2",
"output": "1/6"
},
{
"input": "6 3",
"output": "1/6"
},
{
"input": "6 4",
"output": "1/6"
},
{
"input": "6 5",
"output": "1/6"
},
{
"input": "6 6",
"output": "1/6"
}
] | 1,601,014,552
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 1
| 624
| 10,137,600
|
Y,W=map(int,input().split())
a=max(Y,W)
from fractions import Fraction
print(Fraction((6-(a-1))/6))
|
Title: Die Roll
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
Yakko, Wakko and Dot, world-famous animaniacs, decided to rest from acting in cartoons, and take a leave to travel a bit. Yakko dreamt to go to Pennsylvania, his Motherland and the Motherland of his ancestors. Wakko thought about Tasmania, its beaches, sun and sea. Dot chose Transylvania as the most mysterious and unpredictable place.
But to their great regret, the leave turned to be very short, so it will be enough to visit one of the three above named places. That's why Yakko, as the cleverest, came up with a truly genius idea: let each of the three roll an ordinary six-sided die, and the one with the highest amount of points will be the winner, and will take the other two to the place of his/her dreams.
Yakko thrown a die and got Y points, Wakko — W points. It was Dot's turn. But she didn't hurry. Dot wanted to know for sure what were her chances to visit Transylvania.
It is known that Yakko and Wakko are true gentlemen, that's why if they have the same amount of points with Dot, they will let Dot win.
Input Specification:
The only line of the input file contains two natural numbers Y and W — the results of Yakko's and Wakko's die rolls.
Output Specification:
Output the required probability in the form of irreducible fraction in format «A/B», where A — the numerator, and B — the denominator. If the required probability equals to zero, output «0/1». If the required probability equals to 1, output «1/1».
Demo Input:
['4 2\n']
Demo Output:
['1/2\n']
Note:
Dot will go to Transylvania, if she is lucky to roll 4, 5 or 6 points.
|
```python
Y,W=map(int,input().split())
a=max(Y,W)
from fractions import Fraction
print(Fraction((6-(a-1))/6))
```
| 0
|
163
|
A
|
Substring and Subsequence
|
PROGRAMMING
| 1,700
|
[
"dp"
] | null | null |
One day Polycarpus got hold of two non-empty strings *s* and *t*, consisting of lowercase Latin letters. Polycarpus is quite good with strings, so he immediately wondered, how many different pairs of "*x* *y*" are there, such that *x* is a substring of string *s*, *y* is a subsequence of string *t*, and the content of *x* and *y* is the same. Two pairs are considered different, if they contain different substrings of string *s* or different subsequences of string *t*. Read the whole statement to understand the definition of different substrings and subsequences.
The length of string *s* is the number of characters in it. If we denote the length of the string *s* as |*s*|, we can write the string as *s*<==<=*s*1*s*2... *s*|*s*|.
A substring of *s* is a non-empty string *x*<==<=*s*[*a*... *b*]<==<=*s**a**s**a*<=+<=1... *s**b* (1<=≤<=*a*<=≤<=*b*<=≤<=|*s*|). For example, "code" and "force" are substrings or "codeforces", while "coders" is not. Two substrings *s*[*a*... *b*] and *s*[*c*... *d*] are considered to be different if *a*<=≠<=*c* or *b*<=≠<=*d*. For example, if *s*="codeforces", *s*[2...2] and *s*[6...6] are different, though their content is the same.
A subsequence of *s* is a non-empty string *y*<==<=*s*[*p*1*p*2... *p*|*y*|]<==<=*s**p*1*s**p*2... *s**p*|*y*| (1<=≤<=*p*1<=<<=*p*2<=<<=...<=<<=*p*|*y*|<=≤<=|*s*|). For example, "coders" is a subsequence of "codeforces". Two subsequences *u*<==<=*s*[*p*1*p*2... *p*|*u*|] and *v*<==<=*s*[*q*1*q*2... *q*|*v*|] are considered different if the sequences *p* and *q* are different.
|
The input consists of two lines. The first of them contains *s* (1<=≤<=|*s*|<=≤<=5000), and the second one contains *t* (1<=≤<=|*t*|<=≤<=5000). Both strings consist of lowercase Latin letters.
|
Print a single number — the number of different pairs "*x* *y*" such that *x* is a substring of string *s*, *y* is a subsequence of string *t*, and the content of *x* and *y* is the same. As the answer can be rather large, print it modulo 1000000007 (109<=+<=7).
|
[
"aa\naa\n",
"codeforces\nforceofcode\n"
] |
[
"5\n",
"60\n"
] |
Let's write down all pairs "*x* *y*" that form the answer in the first sample: "*s*[1...1] *t*[1]", "*s*[2...2] *t*[1]", "*s*[1...1] *t*[2]","*s*[2...2] *t*[2]", "*s*[1...2] *t*[1 2]".
| 1,000
|
[
{
"input": "aa\naa",
"output": "5"
},
{
"input": "codeforces\nforceofcode",
"output": "60"
},
{
"input": "coderscontest\ncodeforces",
"output": "39"
},
{
"input": "a\nb",
"output": "0"
},
{
"input": "ab\nbbbba",
"output": "5"
},
{
"input": "abbbccbba\nabcabc",
"output": "33"
},
{
"input": "zxzxzxzxzxzxzx\nd",
"output": "0"
},
{
"input": "pfdempfohomnpgbeegikfmflnalbbajpnpgeacaicoehopgnabnklheepnlnflohjegcciflmfjhachnhekckfjgoffhkblncidn\nidlhklpclcghngeggpjdgefccihndpoikojdjnbkdfjgaanoolfmnifnmbpeeghpicehjdiipnlfnjpglidpnnnjfmjfhbcogojkcfflmmfcgajbjbfaikhmjofbnjnaolbcdkelcieeodbfjcfiblhhmeelmpcmmcdhjcnnfklgedjjbaljndjonanlojclboeelkab",
"output": "26774278"
},
{
"input": "sbypoaavsbqxfiqvpbjyimhzotlxuramhdamvyobsgaehwhtfdvgvlxpophtvzrmvyxwyzeauyatzitsqvlabufbcefaivwzoccfvhrdbzlmzoofczqzbxoqioctzzxqksuorhnldrfavlhyfyobvnqsyegsbvlusxchixbddzbwwnvuulcarguxvnvzkdqcjxxdetll\nlbawrainjjdgkdmwkqzxlwxhzjyrxbuwjhnvjlnmgfyrxdynsanvibfhngsioisbyldaplituqhebeicpsyerpiiqpjtnxvuotjv",
"output": "8095"
},
{
"input": "ababbabbab\nababb",
"output": "75"
},
{
"input": "bbabb\nbababbbbab",
"output": "222"
},
{
"input": "ababababab\nababb",
"output": "74"
},
{
"input": "b\nab",
"output": "1"
},
{
"input": "ab\na",
"output": "1"
},
{
"input": "xzzxxxzxzzzxzzzxxzzxzzxzxzxxzxxzxxzxzzxxzxxzxxxzxzxzxxzzxxxxzxzzzxxxzxzxxxzzxxzxxzxxzzxxzxxzxzxzzzxzzzzxzxxzzxzxxzxxzzxzxzx\nzzx",
"output": "291"
},
{
"input": "zxx\nxzzxxxxzzzxxxzzxxxzxxxzzxxzxxxzzxzxxzxxzxxzxzxxzxxxxzzxxzzxzzxxzzxxzxzxzxxzxzxzxxxzxxzzxxzxxxxzzxxxzxxxzxzxzzxzzxxxxzzxxzxz",
"output": "46917"
}
] | 1,617,956,166
| 2,147,483,647
|
PyPy 3
|
MEMORY_LIMIT_EXCEEDED
|
TESTS
| 7
| 1,590
| 268,390,400
|
s=input().strip()
t=input().strip()
n,m=len(s),len(t)
mod=10**9+7
dp12=[[0 for i in range(m)]for j in range(n) ]
#print(dp)
for i in range(n):
if t[0]==s[i]:
dp12[i][0]=1
for i in range(m):
if s[0]==t[i] :
dp12[0][i]=dp12[0][i-1]+1
else:
dp12[0][i]=dp12[0][i-1]
for i in range(1,n):
for j in range(1,m):
if s[i]==t[j]:
dp12[i][j]=max(1,dp12[i][j], (dp12[i-1][j-1]+dp12[i][j-1]+1))
else:
dp12[i][j]=dp12[i][j-1]
an=0
for i in range(n):
an+=dp12[i][-1]
print(an)
|
Title: Substring and Subsequence
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day Polycarpus got hold of two non-empty strings *s* and *t*, consisting of lowercase Latin letters. Polycarpus is quite good with strings, so he immediately wondered, how many different pairs of "*x* *y*" are there, such that *x* is a substring of string *s*, *y* is a subsequence of string *t*, and the content of *x* and *y* is the same. Two pairs are considered different, if they contain different substrings of string *s* or different subsequences of string *t*. Read the whole statement to understand the definition of different substrings and subsequences.
The length of string *s* is the number of characters in it. If we denote the length of the string *s* as |*s*|, we can write the string as *s*<==<=*s*1*s*2... *s*|*s*|.
A substring of *s* is a non-empty string *x*<==<=*s*[*a*... *b*]<==<=*s**a**s**a*<=+<=1... *s**b* (1<=≤<=*a*<=≤<=*b*<=≤<=|*s*|). For example, "code" and "force" are substrings or "codeforces", while "coders" is not. Two substrings *s*[*a*... *b*] and *s*[*c*... *d*] are considered to be different if *a*<=≠<=*c* or *b*<=≠<=*d*. For example, if *s*="codeforces", *s*[2...2] and *s*[6...6] are different, though their content is the same.
A subsequence of *s* is a non-empty string *y*<==<=*s*[*p*1*p*2... *p*|*y*|]<==<=*s**p*1*s**p*2... *s**p*|*y*| (1<=≤<=*p*1<=<<=*p*2<=<<=...<=<<=*p*|*y*|<=≤<=|*s*|). For example, "coders" is a subsequence of "codeforces". Two subsequences *u*<==<=*s*[*p*1*p*2... *p*|*u*|] and *v*<==<=*s*[*q*1*q*2... *q*|*v*|] are considered different if the sequences *p* and *q* are different.
Input Specification:
The input consists of two lines. The first of them contains *s* (1<=≤<=|*s*|<=≤<=5000), and the second one contains *t* (1<=≤<=|*t*|<=≤<=5000). Both strings consist of lowercase Latin letters.
Output Specification:
Print a single number — the number of different pairs "*x* *y*" such that *x* is a substring of string *s*, *y* is a subsequence of string *t*, and the content of *x* and *y* is the same. As the answer can be rather large, print it modulo 1000000007 (109<=+<=7).
Demo Input:
['aa\naa\n', 'codeforces\nforceofcode\n']
Demo Output:
['5\n', '60\n']
Note:
Let's write down all pairs "*x* *y*" that form the answer in the first sample: "*s*[1...1] *t*[1]", "*s*[2...2] *t*[1]", "*s*[1...1] *t*[2]","*s*[2...2] *t*[2]", "*s*[1...2] *t*[1 2]".
|
```python
s=input().strip()
t=input().strip()
n,m=len(s),len(t)
mod=10**9+7
dp12=[[0 for i in range(m)]for j in range(n) ]
#print(dp)
for i in range(n):
if t[0]==s[i]:
dp12[i][0]=1
for i in range(m):
if s[0]==t[i] :
dp12[0][i]=dp12[0][i-1]+1
else:
dp12[0][i]=dp12[0][i-1]
for i in range(1,n):
for j in range(1,m):
if s[i]==t[j]:
dp12[i][j]=max(1,dp12[i][j], (dp12[i-1][j-1]+dp12[i][j-1]+1))
else:
dp12[i][j]=dp12[i][j-1]
an=0
for i in range(n):
an+=dp12[i][-1]
print(an)
```
| 0
|
|
557
|
B
|
Pasha and Tea
|
PROGRAMMING
| 1,500
|
[
"constructive algorithms",
"implementation",
"math",
"sortings"
] | null | null |
Pasha decided to invite his friends to a tea party. For that occasion, he has a large teapot with the capacity of *w* milliliters and 2*n* tea cups, each cup is for one of Pasha's friends. The *i*-th cup can hold at most *a**i* milliliters of water.
It turned out that among Pasha's friends there are exactly *n* boys and exactly *n* girls and all of them are going to come to the tea party. To please everyone, Pasha decided to pour the water for the tea as follows:
- Pasha can boil the teapot exactly once by pouring there at most *w* milliliters of water; - Pasha pours the same amount of water to each girl; - Pasha pours the same amount of water to each boy; - if each girl gets *x* milliliters of water, then each boy gets 2*x* milliliters of water.
In the other words, each boy should get two times more water than each girl does.
Pasha is very kind and polite, so he wants to maximize the total amount of the water that he pours to his friends. Your task is to help him and determine the optimum distribution of cups between Pasha's friends.
|
The first line of the input contains two integers, *n* and *w* (1<=≤<=*n*<=≤<=105, 1<=≤<=*w*<=≤<=109) — the number of Pasha's friends that are boys (equal to the number of Pasha's friends that are girls) and the capacity of Pasha's teapot in milliliters.
The second line of the input contains the sequence of integers *a**i* (1<=≤<=*a**i*<=≤<=109, 1<=≤<=*i*<=≤<=2*n*) — the capacities of Pasha's tea cups in milliliters.
|
Print a single real number — the maximum total amount of water in milliliters that Pasha can pour to his friends without violating the given conditions. Your answer will be considered correct if its absolute or relative error doesn't exceed 10<=-<=6.
|
[
"2 4\n1 1 1 1\n",
"3 18\n4 4 4 2 2 2\n",
"1 5\n2 3\n"
] |
[
"3",
"18",
"4.5"
] |
Pasha also has candies that he is going to give to girls but that is another task...
| 1,000
|
[
{
"input": "2 4\n1 1 1 1",
"output": "3.0000000000"
},
{
"input": "3 18\n4 4 4 2 2 2",
"output": "18.0000000000"
},
{
"input": "1 5\n2 3",
"output": "4.5000000000"
},
{
"input": "1 1\n1000000000 1000000000",
"output": "1.0000000000"
},
{
"input": "4 1000000000\n1 1 1 1 1 1 1 1",
"output": "6.0000000000"
},
{
"input": "4 1000000000\n1 1 1 1 2 2 2 2",
"output": "12.0000000000"
},
{
"input": "4 1\n3 3 3 3 4 4 4 4",
"output": "1.0000000000"
},
{
"input": "2 19\n3 3 5 5",
"output": "15.0000000000"
},
{
"input": "3 31\n3 3 3 5 5 5",
"output": "22.5000000000"
},
{
"input": "5 15\n2 3 4 1 2 4 5 3 5 10",
"output": "15.0000000000"
},
{
"input": "5 14\n2 3 4 1 2 4 5 3 5 10",
"output": "14.0000000000"
},
{
"input": "5 16\n2 3 4 1 2 4 5 3 5 10",
"output": "15.0000000000"
},
{
"input": "1 100\n1 200",
"output": "3.0000000000"
},
{
"input": "1 1\n1 1",
"output": "1.0000000000"
},
{
"input": "2 1000000000\n1 1 1 100",
"output": "3.0000000000"
},
{
"input": "4 30\n3 3 3 3 4 5 6 7",
"output": "24.0000000000"
},
{
"input": "2 100\n1 1 1 10",
"output": "3.0000000000"
},
{
"input": "3 18\n1 1 1 1 1 5",
"output": "4.5000000000"
}
] | 1,435,677,871
| 1,471
|
Python 3
|
COMPILATION_ERROR
|
PRETESTS
| 0
| 0
| 0
|
#include<cstdio>
#include<iostream>
#include<cstring>
#include<string>
#include<algorithm>
#include<vector>
#include<cmath>
#include<set>
#include<map>
#include<queue>
using namespace std;
int a[200005];
int main(){
int i,j,m,n;
cin>>n>>m;
for(i=1;i<=2*n;i++)scanf("%d",&a[i]);
sort(a+1,a+2*n+1);
int t=a[n+1];
if(t>a[1]*2)t=a[1]*2;
double ans=1.5*t*n;
if(ans>m)ans=m;
cout<<ans<<endl;
return 0;
}
|
Title: Pasha and Tea
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Pasha decided to invite his friends to a tea party. For that occasion, he has a large teapot with the capacity of *w* milliliters and 2*n* tea cups, each cup is for one of Pasha's friends. The *i*-th cup can hold at most *a**i* milliliters of water.
It turned out that among Pasha's friends there are exactly *n* boys and exactly *n* girls and all of them are going to come to the tea party. To please everyone, Pasha decided to pour the water for the tea as follows:
- Pasha can boil the teapot exactly once by pouring there at most *w* milliliters of water; - Pasha pours the same amount of water to each girl; - Pasha pours the same amount of water to each boy; - if each girl gets *x* milliliters of water, then each boy gets 2*x* milliliters of water.
In the other words, each boy should get two times more water than each girl does.
Pasha is very kind and polite, so he wants to maximize the total amount of the water that he pours to his friends. Your task is to help him and determine the optimum distribution of cups between Pasha's friends.
Input Specification:
The first line of the input contains two integers, *n* and *w* (1<=≤<=*n*<=≤<=105, 1<=≤<=*w*<=≤<=109) — the number of Pasha's friends that are boys (equal to the number of Pasha's friends that are girls) and the capacity of Pasha's teapot in milliliters.
The second line of the input contains the sequence of integers *a**i* (1<=≤<=*a**i*<=≤<=109, 1<=≤<=*i*<=≤<=2*n*) — the capacities of Pasha's tea cups in milliliters.
Output Specification:
Print a single real number — the maximum total amount of water in milliliters that Pasha can pour to his friends without violating the given conditions. Your answer will be considered correct if its absolute or relative error doesn't exceed 10<=-<=6.
Demo Input:
['2 4\n1 1 1 1\n', '3 18\n4 4 4 2 2 2\n', '1 5\n2 3\n']
Demo Output:
['3', '18', '4.5']
Note:
Pasha also has candies that he is going to give to girls but that is another task...
|
```python
#include<cstdio>
#include<iostream>
#include<cstring>
#include<string>
#include<algorithm>
#include<vector>
#include<cmath>
#include<set>
#include<map>
#include<queue>
using namespace std;
int a[200005];
int main(){
int i,j,m,n;
cin>>n>>m;
for(i=1;i<=2*n;i++)scanf("%d",&a[i]);
sort(a+1,a+2*n+1);
int t=a[n+1];
if(t>a[1]*2)t=a[1]*2;
double ans=1.5*t*n;
if(ans>m)ans=m;
cout<<ans<<endl;
return 0;
}
```
| -1
|
|
987
|
A
|
Infinity Gauntlet
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
You took a peek on Thanos wearing Infinity Gauntlet. In the Gauntlet there is a place for six Infinity Gems:
- the Power Gem of purple color, - the Time Gem of green color, - the Space Gem of blue color, - the Soul Gem of orange color, - the Reality Gem of red color, - the Mind Gem of yellow color.
Using colors of Gems you saw in the Gauntlet determine the names of absent Gems.
|
In the first line of input there is one integer $n$ ($0 \le n \le 6$) — the number of Gems in Infinity Gauntlet.
In next $n$ lines there are colors of Gems you saw. Words used for colors are: purple, green, blue, orange, red, yellow. It is guaranteed that all the colors are distinct. All colors are given in lowercase English letters.
|
In the first line output one integer $m$ ($0 \le m \le 6$) — the number of absent Gems.
Then in $m$ lines print the names of absent Gems, each on its own line. Words used for names are: Power, Time, Space, Soul, Reality, Mind. Names can be printed in any order. Keep the first letter uppercase, others lowercase.
|
[
"4\nred\npurple\nyellow\norange\n",
"0\n"
] |
[
"2\nSpace\nTime\n",
"6\nTime\nMind\nSoul\nPower\nReality\nSpace\n"
] |
In the first sample Thanos already has Reality, Power, Mind and Soul Gems, so he needs two more: Time and Space.
In the second sample Thanos doesn't have any Gems, so he needs all six.
| 500
|
[
{
"input": "4\nred\npurple\nyellow\norange",
"output": "2\nSpace\nTime"
},
{
"input": "0",
"output": "6\nMind\nSpace\nPower\nTime\nReality\nSoul"
},
{
"input": "6\npurple\nblue\nyellow\nred\ngreen\norange",
"output": "0"
},
{
"input": "1\npurple",
"output": "5\nTime\nReality\nSoul\nSpace\nMind"
},
{
"input": "3\nblue\norange\npurple",
"output": "3\nTime\nReality\nMind"
},
{
"input": "2\nyellow\nred",
"output": "4\nPower\nSoul\nSpace\nTime"
},
{
"input": "1\ngreen",
"output": "5\nReality\nSpace\nPower\nSoul\nMind"
},
{
"input": "2\npurple\ngreen",
"output": "4\nReality\nMind\nSpace\nSoul"
},
{
"input": "1\nblue",
"output": "5\nPower\nReality\nSoul\nTime\nMind"
},
{
"input": "2\npurple\nblue",
"output": "4\nMind\nSoul\nTime\nReality"
},
{
"input": "2\ngreen\nblue",
"output": "4\nReality\nMind\nPower\nSoul"
},
{
"input": "3\npurple\ngreen\nblue",
"output": "3\nMind\nReality\nSoul"
},
{
"input": "1\norange",
"output": "5\nReality\nTime\nPower\nSpace\nMind"
},
{
"input": "2\npurple\norange",
"output": "4\nReality\nMind\nTime\nSpace"
},
{
"input": "2\norange\ngreen",
"output": "4\nSpace\nMind\nReality\nPower"
},
{
"input": "3\norange\npurple\ngreen",
"output": "3\nReality\nSpace\nMind"
},
{
"input": "2\norange\nblue",
"output": "4\nTime\nMind\nReality\nPower"
},
{
"input": "3\nblue\ngreen\norange",
"output": "3\nPower\nMind\nReality"
},
{
"input": "4\nblue\norange\ngreen\npurple",
"output": "2\nMind\nReality"
},
{
"input": "1\nred",
"output": "5\nTime\nSoul\nMind\nPower\nSpace"
},
{
"input": "2\nred\npurple",
"output": "4\nMind\nSpace\nTime\nSoul"
},
{
"input": "2\nred\ngreen",
"output": "4\nMind\nSpace\nPower\nSoul"
},
{
"input": "3\nred\npurple\ngreen",
"output": "3\nSoul\nSpace\nMind"
},
{
"input": "2\nblue\nred",
"output": "4\nMind\nTime\nPower\nSoul"
},
{
"input": "3\nred\nblue\npurple",
"output": "3\nTime\nMind\nSoul"
},
{
"input": "3\nred\nblue\ngreen",
"output": "3\nSoul\nPower\nMind"
},
{
"input": "4\npurple\nblue\ngreen\nred",
"output": "2\nMind\nSoul"
},
{
"input": "2\norange\nred",
"output": "4\nPower\nMind\nTime\nSpace"
},
{
"input": "3\nred\norange\npurple",
"output": "3\nMind\nSpace\nTime"
},
{
"input": "3\nred\norange\ngreen",
"output": "3\nMind\nSpace\nPower"
},
{
"input": "4\nred\norange\ngreen\npurple",
"output": "2\nSpace\nMind"
},
{
"input": "3\nblue\norange\nred",
"output": "3\nPower\nMind\nTime"
},
{
"input": "4\norange\nblue\npurple\nred",
"output": "2\nTime\nMind"
},
{
"input": "4\ngreen\norange\nred\nblue",
"output": "2\nMind\nPower"
},
{
"input": "5\npurple\norange\nblue\nred\ngreen",
"output": "1\nMind"
},
{
"input": "1\nyellow",
"output": "5\nPower\nSoul\nReality\nSpace\nTime"
},
{
"input": "2\npurple\nyellow",
"output": "4\nTime\nReality\nSpace\nSoul"
},
{
"input": "2\ngreen\nyellow",
"output": "4\nSpace\nReality\nPower\nSoul"
},
{
"input": "3\npurple\nyellow\ngreen",
"output": "3\nSoul\nReality\nSpace"
},
{
"input": "2\nblue\nyellow",
"output": "4\nTime\nReality\nPower\nSoul"
},
{
"input": "3\nyellow\nblue\npurple",
"output": "3\nSoul\nReality\nTime"
},
{
"input": "3\ngreen\nyellow\nblue",
"output": "3\nSoul\nReality\nPower"
},
{
"input": "4\nyellow\nblue\ngreen\npurple",
"output": "2\nReality\nSoul"
},
{
"input": "2\nyellow\norange",
"output": "4\nTime\nSpace\nReality\nPower"
},
{
"input": "3\nyellow\npurple\norange",
"output": "3\nSpace\nReality\nTime"
},
{
"input": "3\norange\nyellow\ngreen",
"output": "3\nSpace\nReality\nPower"
},
{
"input": "4\ngreen\nyellow\norange\npurple",
"output": "2\nSpace\nReality"
},
{
"input": "3\nyellow\nblue\norange",
"output": "3\nTime\nReality\nPower"
},
{
"input": "4\norange\npurple\nblue\nyellow",
"output": "2\nReality\nTime"
},
{
"input": "4\nblue\norange\nyellow\ngreen",
"output": "2\nReality\nPower"
},
{
"input": "5\ngreen\nyellow\norange\nblue\npurple",
"output": "1\nReality"
},
{
"input": "3\nyellow\npurple\nred",
"output": "3\nTime\nSoul\nSpace"
},
{
"input": "3\nred\ngreen\nyellow",
"output": "3\nPower\nSoul\nSpace"
},
{
"input": "4\nred\npurple\ngreen\nyellow",
"output": "2\nSpace\nSoul"
},
{
"input": "3\nred\nyellow\nblue",
"output": "3\nPower\nSoul\nTime"
},
{
"input": "4\nblue\nyellow\nred\npurple",
"output": "2\nTime\nSoul"
},
{
"input": "4\nblue\nyellow\nred\ngreen",
"output": "2\nSoul\nPower"
},
{
"input": "5\nred\nyellow\ngreen\nblue\npurple",
"output": "1\nSoul"
},
{
"input": "3\nred\nyellow\norange",
"output": "3\nPower\nSpace\nTime"
},
{
"input": "4\norange\ngreen\nyellow\nred",
"output": "2\nPower\nSpace"
},
{
"input": "5\norange\nred\ngreen\nyellow\npurple",
"output": "1\nSpace"
},
{
"input": "4\nyellow\nred\norange\nblue",
"output": "2\nTime\nPower"
},
{
"input": "5\npurple\nblue\norange\nyellow\nred",
"output": "1\nTime"
},
{
"input": "5\norange\nblue\nyellow\nred\ngreen",
"output": "1\nPower"
}
] | 1,616,692,880
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 64
| 108
| 0
|
dict1 = {"purple": "Power", "green": "Time", "blue": "Space", "orange": "Soul", "red": "Reality", "yellow": "Mind"}
s = set()
a = int(input())
for q in range(a):
b = input()
s.add(b)
print(6 - a)
for (key, value) in dict1.items():
if key not in s:
print(value)
|
Title: Infinity Gauntlet
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You took a peek on Thanos wearing Infinity Gauntlet. In the Gauntlet there is a place for six Infinity Gems:
- the Power Gem of purple color, - the Time Gem of green color, - the Space Gem of blue color, - the Soul Gem of orange color, - the Reality Gem of red color, - the Mind Gem of yellow color.
Using colors of Gems you saw in the Gauntlet determine the names of absent Gems.
Input Specification:
In the first line of input there is one integer $n$ ($0 \le n \le 6$) — the number of Gems in Infinity Gauntlet.
In next $n$ lines there are colors of Gems you saw. Words used for colors are: purple, green, blue, orange, red, yellow. It is guaranteed that all the colors are distinct. All colors are given in lowercase English letters.
Output Specification:
In the first line output one integer $m$ ($0 \le m \le 6$) — the number of absent Gems.
Then in $m$ lines print the names of absent Gems, each on its own line. Words used for names are: Power, Time, Space, Soul, Reality, Mind. Names can be printed in any order. Keep the first letter uppercase, others lowercase.
Demo Input:
['4\nred\npurple\nyellow\norange\n', '0\n']
Demo Output:
['2\nSpace\nTime\n', '6\nTime\nMind\nSoul\nPower\nReality\nSpace\n']
Note:
In the first sample Thanos already has Reality, Power, Mind and Soul Gems, so he needs two more: Time and Space.
In the second sample Thanos doesn't have any Gems, so he needs all six.
|
```python
dict1 = {"purple": "Power", "green": "Time", "blue": "Space", "orange": "Soul", "red": "Reality", "yellow": "Mind"}
s = set()
a = int(input())
for q in range(a):
b = input()
s.add(b)
print(6 - a)
for (key, value) in dict1.items():
if key not in s:
print(value)
```
| 3
|
|
451
|
A
|
Game With Sticks
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
After winning gold and silver in IOI 2014, Akshat and Malvika want to have some fun. Now they are playing a game on a grid made of *n* horizontal and *m* vertical sticks.
An intersection point is any point on the grid which is formed by the intersection of one horizontal stick and one vertical stick.
In the grid shown below, *n*<==<=3 and *m*<==<=3. There are *n*<=+<=*m*<==<=6 sticks in total (horizontal sticks are shown in red and vertical sticks are shown in green). There are *n*·*m*<==<=9 intersection points, numbered from 1 to 9.
The rules of the game are very simple. The players move in turns. Akshat won gold, so he makes the first move. During his/her move, a player must choose any remaining intersection point and remove from the grid all sticks which pass through this point. A player will lose the game if he/she cannot make a move (i.e. there are no intersection points remaining on the grid at his/her move).
Assume that both players play optimally. Who will win the game?
|
The first line of input contains two space-separated integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100).
|
Print a single line containing "Akshat" or "Malvika" (without the quotes), depending on the winner of the game.
|
[
"2 2\n",
"2 3\n",
"3 3\n"
] |
[
"Malvika\n",
"Malvika\n",
"Akshat\n"
] |
Explanation of the first sample:
The grid has four intersection points, numbered from 1 to 4.
If Akshat chooses intersection point 1, then he will remove two sticks (1 - 2 and 1 - 3). The resulting grid will look like this.
Now there is only one remaining intersection point (i.e. 4). Malvika must choose it and remove both remaining sticks. After her move the grid will be empty.
In the empty grid, Akshat cannot make any move, hence he will lose.
Since all 4 intersection points of the grid are equivalent, Akshat will lose no matter which one he picks.
| 500
|
[
{
"input": "2 2",
"output": "Malvika"
},
{
"input": "2 3",
"output": "Malvika"
},
{
"input": "3 3",
"output": "Akshat"
},
{
"input": "20 68",
"output": "Malvika"
},
{
"input": "1 1",
"output": "Akshat"
},
{
"input": "1 2",
"output": "Akshat"
},
{
"input": "1 3",
"output": "Akshat"
},
{
"input": "2 1",
"output": "Akshat"
},
{
"input": "2 2",
"output": "Malvika"
},
{
"input": "3 1",
"output": "Akshat"
},
{
"input": "3 2",
"output": "Malvika"
},
{
"input": "68 42",
"output": "Malvika"
},
{
"input": "1 35",
"output": "Akshat"
},
{
"input": "25 70",
"output": "Akshat"
},
{
"input": "59 79",
"output": "Akshat"
},
{
"input": "65 63",
"output": "Akshat"
},
{
"input": "46 6",
"output": "Malvika"
},
{
"input": "28 82",
"output": "Malvika"
},
{
"input": "98 98",
"output": "Malvika"
},
{
"input": "98 99",
"output": "Malvika"
},
{
"input": "98 100",
"output": "Malvika"
},
{
"input": "99 98",
"output": "Malvika"
},
{
"input": "99 99",
"output": "Akshat"
},
{
"input": "99 100",
"output": "Akshat"
},
{
"input": "100 98",
"output": "Malvika"
},
{
"input": "100 99",
"output": "Akshat"
},
{
"input": "100 100",
"output": "Malvika"
},
{
"input": "3 4",
"output": "Akshat"
}
] | 1,681,835,686
| 2,147,483,647
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 1
| 31
| 0
|
n,m=map(int,input().split())
if n==m:
if n%2==0:
print("Malvika")
else:
print("Akshat")
else:
num=min(n,m)+math.abs(n-m)
if num%2==0:
print("Malvika")
else:
print("Akshat")
|
Title: Game With Sticks
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
After winning gold and silver in IOI 2014, Akshat and Malvika want to have some fun. Now they are playing a game on a grid made of *n* horizontal and *m* vertical sticks.
An intersection point is any point on the grid which is formed by the intersection of one horizontal stick and one vertical stick.
In the grid shown below, *n*<==<=3 and *m*<==<=3. There are *n*<=+<=*m*<==<=6 sticks in total (horizontal sticks are shown in red and vertical sticks are shown in green). There are *n*·*m*<==<=9 intersection points, numbered from 1 to 9.
The rules of the game are very simple. The players move in turns. Akshat won gold, so he makes the first move. During his/her move, a player must choose any remaining intersection point and remove from the grid all sticks which pass through this point. A player will lose the game if he/she cannot make a move (i.e. there are no intersection points remaining on the grid at his/her move).
Assume that both players play optimally. Who will win the game?
Input Specification:
The first line of input contains two space-separated integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100).
Output Specification:
Print a single line containing "Akshat" or "Malvika" (without the quotes), depending on the winner of the game.
Demo Input:
['2 2\n', '2 3\n', '3 3\n']
Demo Output:
['Malvika\n', 'Malvika\n', 'Akshat\n']
Note:
Explanation of the first sample:
The grid has four intersection points, numbered from 1 to 4.
If Akshat chooses intersection point 1, then he will remove two sticks (1 - 2 and 1 - 3). The resulting grid will look like this.
Now there is only one remaining intersection point (i.e. 4). Malvika must choose it and remove both remaining sticks. After her move the grid will be empty.
In the empty grid, Akshat cannot make any move, hence he will lose.
Since all 4 intersection points of the grid are equivalent, Akshat will lose no matter which one he picks.
|
```python
n,m=map(int,input().split())
if n==m:
if n%2==0:
print("Malvika")
else:
print("Akshat")
else:
num=min(n,m)+math.abs(n-m)
if num%2==0:
print("Malvika")
else:
print("Akshat")
```
| -1
|
|
365
|
A
|
Good Number
|
PROGRAMMING
| 1,100
|
[
"implementation"
] | null | null |
Let's call a number *k*-good if it contains all digits not exceeding *k* (0,<=...,<=*k*). You've got a number *k* and an array *a* containing *n* numbers. Find out how many *k*-good numbers are in *a* (count each number every time it occurs in array *a*).
|
The first line contains integers *n* and *k* (1<=≤<=*n*<=≤<=100, 0<=≤<=*k*<=≤<=9). The *i*-th of the following *n* lines contains integer *a**i* without leading zeroes (1<=≤<=*a**i*<=≤<=109).
|
Print a single integer — the number of *k*-good numbers in *a*.
|
[
"10 6\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n",
"2 1\n1\n10\n"
] |
[
"10\n",
"1\n"
] |
none
| 500
|
[
{
"input": "10 6\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560",
"output": "10"
},
{
"input": "2 1\n1\n10",
"output": "1"
},
{
"input": "1 0\n1000000000",
"output": "1"
},
{
"input": "1 1\n1000000000",
"output": "1"
},
{
"input": "6 0\n10\n102\n120\n1032\n1212103\n1999999",
"output": "5"
},
{
"input": "1 3\n1000000000",
"output": "0"
},
{
"input": "1 9\n1000000000",
"output": "0"
},
{
"input": "1 0\n1",
"output": "0"
},
{
"input": "1 1\n1",
"output": "0"
},
{
"input": "1 3\n1",
"output": "0"
},
{
"input": "1 9\n1",
"output": "0"
},
{
"input": "2 8\n123456780\n123",
"output": "1"
},
{
"input": "2 8\n12345678\n1230",
"output": "0"
},
{
"input": "6 1\n10\n102\n120\n1032\n1212103\n1999999",
"output": "5"
},
{
"input": "6 2\n10\n102\n120\n1032\n1212103\n1999999",
"output": "4"
},
{
"input": "6 3\n10\n102\n120\n1032\n1212103\n1999999",
"output": "2"
},
{
"input": "6 9\n10\n102\n120\n1032\n1212103\n1999999",
"output": "0"
},
{
"input": "1 2\n2220",
"output": "0"
}
] | 1,640,676,192
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 37
| 46
| 0
|
b=list(map(int,input().split()))
c=0
for i in range(b[0]):
a=input()
for j in range(0,(b[1]+1)):
if str(j) in a:
k=1
else:
k=0
break
if k==1:
c=c+1
print(c)
|
Title: Good Number
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Let's call a number *k*-good if it contains all digits not exceeding *k* (0,<=...,<=*k*). You've got a number *k* and an array *a* containing *n* numbers. Find out how many *k*-good numbers are in *a* (count each number every time it occurs in array *a*).
Input Specification:
The first line contains integers *n* and *k* (1<=≤<=*n*<=≤<=100, 0<=≤<=*k*<=≤<=9). The *i*-th of the following *n* lines contains integer *a**i* without leading zeroes (1<=≤<=*a**i*<=≤<=109).
Output Specification:
Print a single integer — the number of *k*-good numbers in *a*.
Demo Input:
['10 6\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n1234560\n', '2 1\n1\n10\n']
Demo Output:
['10\n', '1\n']
Note:
none
|
```python
b=list(map(int,input().split()))
c=0
for i in range(b[0]):
a=input()
for j in range(0,(b[1]+1)):
if str(j) in a:
k=1
else:
k=0
break
if k==1:
c=c+1
print(c)
```
| 3
|
|
496
|
A
|
Minimum Difficulty
|
PROGRAMMING
| 900
|
[
"brute force",
"implementation",
"math"
] | null | null |
Mike is trying rock climbing but he is awful at it.
There are *n* holds on the wall, *i*-th hold is at height *a**i* off the ground. Besides, let the sequence *a**i* increase, that is, *a**i*<=<<=*a**i*<=+<=1 for all *i* from 1 to *n*<=-<=1; we will call such sequence a track. Mike thinks that the track *a*1, ..., *a**n* has difficulty . In other words, difficulty equals the maximum distance between two holds that are adjacent in height.
Today Mike decided to cover the track with holds hanging on heights *a*1, ..., *a**n*. To make the problem harder, Mike decided to remove one hold, that is, remove one element of the sequence (for example, if we take the sequence (1,<=2,<=3,<=4,<=5) and remove the third element from it, we obtain the sequence (1,<=2,<=4,<=5)). However, as Mike is awful at climbing, he wants the final difficulty (i.e. the maximum difference of heights between adjacent holds after removing the hold) to be as small as possible among all possible options of removing a hold. The first and last holds must stay at their positions.
Help Mike determine the minimum difficulty of the track after removing one hold.
|
The first line contains a single integer *n* (3<=≤<=*n*<=≤<=100) — the number of holds.
The next line contains *n* space-separated integers *a**i* (1<=≤<=*a**i*<=≤<=1000), where *a**i* is the height where the hold number *i* hangs. The sequence *a**i* is increasing (i.e. each element except for the first one is strictly larger than the previous one).
|
Print a single number — the minimum difficulty of the track after removing a single hold.
|
[
"3\n1 4 6\n",
"5\n1 2 3 4 5\n",
"5\n1 2 3 7 8\n"
] |
[
"5\n",
"2\n",
"4\n"
] |
In the first sample you can remove only the second hold, then the sequence looks like (1, 6), the maximum difference of the neighboring elements equals 5.
In the second test after removing every hold the difficulty equals 2.
In the third test you can obtain sequences (1, 3, 7, 8), (1, 2, 7, 8), (1, 2, 3, 8), for which the difficulty is 4, 5 and 5, respectively. Thus, after removing the second element we obtain the optimal answer — 4.
| 500
|
[
{
"input": "3\n1 4 6",
"output": "5"
},
{
"input": "5\n1 2 3 4 5",
"output": "2"
},
{
"input": "5\n1 2 3 7 8",
"output": "4"
},
{
"input": "3\n1 500 1000",
"output": "999"
},
{
"input": "10\n1 2 3 4 5 6 7 8 9 10",
"output": "2"
},
{
"input": "10\n1 4 9 16 25 36 49 64 81 100",
"output": "19"
},
{
"input": "10\n300 315 325 338 350 365 379 391 404 416",
"output": "23"
},
{
"input": "15\n87 89 91 92 93 95 97 99 101 103 105 107 109 111 112",
"output": "2"
},
{
"input": "60\n3 5 7 8 15 16 18 21 24 26 40 41 43 47 48 49 50 51 52 54 55 60 62 71 74 84 85 89 91 96 406 407 409 412 417 420 423 424 428 431 432 433 436 441 445 446 447 455 458 467 469 471 472 475 480 485 492 493 497 500",
"output": "310"
},
{
"input": "3\n159 282 405",
"output": "246"
},
{
"input": "81\n6 7 22 23 27 38 40 56 59 71 72 78 80 83 86 92 95 96 101 122 125 127 130 134 154 169 170 171 172 174 177 182 184 187 195 197 210 211 217 223 241 249 252 253 256 261 265 269 274 277 291 292 297 298 299 300 302 318 338 348 351 353 381 386 387 397 409 410 419 420 428 430 453 460 461 473 478 493 494 500 741",
"output": "241"
},
{
"input": "10\n218 300 388 448 535 629 680 740 836 925",
"output": "111"
},
{
"input": "100\n6 16 26 36 46 56 66 76 86 96 106 116 126 136 146 156 166 176 186 196 206 216 226 236 246 256 266 276 286 296 306 316 326 336 346 356 366 376 386 396 406 416 426 436 446 456 466 476 486 496 506 516 526 536 546 556 566 576 586 596 606 616 626 636 646 656 666 676 686 696 706 716 726 736 746 756 766 776 786 796 806 816 826 836 846 856 866 876 886 896 906 916 926 936 946 956 966 976 986 996",
"output": "20"
},
{
"input": "100\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 951 952 953 954 955 956 957 958 959 960 961 962 963 964 965 966 967 968 969 970 971 972 973 974 975 976 977 978 979 980 981 982 983 984 985 986 987 988 989 990 991 992 993 994 995 996 997 998 999 1000",
"output": "901"
},
{
"input": "100\n1 9 15 17 28 29 30 31 32 46 48 49 52 56 62 77 82 85 90 91 94 101 102 109 111 113 116 118 124 125 131 132 136 138 139 143 145 158 161 162 165 167 171 173 175 177 179 183 189 196 801 802 804 806 817 819 827 830 837 840 842 846 850 855 858 862 863 866 869 870 878 881 883 884 896 898 899 901 904 906 908 909 910 911 912 917 923 924 925 935 939 943 945 956 963 964 965 972 976 978",
"output": "605"
},
{
"input": "100\n2 43 47 49 50 57 59 67 74 98 901 903 904 906 907 908 909 910 911 912 913 914 915 916 917 918 919 920 921 922 923 924 925 926 927 928 929 930 931 932 933 934 935 936 938 939 940 942 943 944 945 946 947 948 949 950 952 953 954 956 957 958 959 960 961 962 963 965 966 967 968 969 970 971 972 973 974 975 976 978 979 980 981 982 983 984 985 986 987 988 989 990 991 992 993 994 995 996 998 999",
"output": "803"
},
{
"input": "72\n178 186 196 209 217 226 236 248 260 273 281 291 300 309 322 331 343 357 366 377 389 399 409 419 429 442 450 459 469 477 491 501 512 524 534 548 557 568 582 593 602 616 630 643 652 660 670 679 693 707 715 728 737 750 759 768 776 789 797 807 815 827 837 849 863 873 881 890 901 910 920 932",
"output": "17"
},
{
"input": "38\n1 28 55 82 109 136 163 190 217 244 271 298 325 352 379 406 433 460 487 514 541 568 595 622 649 676 703 730 757 784 811 838 865 892 919 946 973 1000",
"output": "54"
},
{
"input": "28\n1 38 75 112 149 186 223 260 297 334 371 408 445 482 519 556 593 630 667 704 741 778 815 852 889 926 963 1000",
"output": "74"
}
] | 1,418,836,261
| 2,461
|
Python 3
|
OK
|
TESTS
| 19
| 46
| 0
|
n = int(input())
a = list(map(int, input(). split()))
sl = []; s2 = []
for i in range(n - 2):
sl += [a[i + 2] - a[i]]
s2 += [a[i + 1] - a[i]]
s2 += [a[-1] - a[-2]]
print(max(min(sl), max(s2)))
|
Title: Minimum Difficulty
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Mike is trying rock climbing but he is awful at it.
There are *n* holds on the wall, *i*-th hold is at height *a**i* off the ground. Besides, let the sequence *a**i* increase, that is, *a**i*<=<<=*a**i*<=+<=1 for all *i* from 1 to *n*<=-<=1; we will call such sequence a track. Mike thinks that the track *a*1, ..., *a**n* has difficulty . In other words, difficulty equals the maximum distance between two holds that are adjacent in height.
Today Mike decided to cover the track with holds hanging on heights *a*1, ..., *a**n*. To make the problem harder, Mike decided to remove one hold, that is, remove one element of the sequence (for example, if we take the sequence (1,<=2,<=3,<=4,<=5) and remove the third element from it, we obtain the sequence (1,<=2,<=4,<=5)). However, as Mike is awful at climbing, he wants the final difficulty (i.e. the maximum difference of heights between adjacent holds after removing the hold) to be as small as possible among all possible options of removing a hold. The first and last holds must stay at their positions.
Help Mike determine the minimum difficulty of the track after removing one hold.
Input Specification:
The first line contains a single integer *n* (3<=≤<=*n*<=≤<=100) — the number of holds.
The next line contains *n* space-separated integers *a**i* (1<=≤<=*a**i*<=≤<=1000), where *a**i* is the height where the hold number *i* hangs. The sequence *a**i* is increasing (i.e. each element except for the first one is strictly larger than the previous one).
Output Specification:
Print a single number — the minimum difficulty of the track after removing a single hold.
Demo Input:
['3\n1 4 6\n', '5\n1 2 3 4 5\n', '5\n1 2 3 7 8\n']
Demo Output:
['5\n', '2\n', '4\n']
Note:
In the first sample you can remove only the second hold, then the sequence looks like (1, 6), the maximum difference of the neighboring elements equals 5.
In the second test after removing every hold the difficulty equals 2.
In the third test you can obtain sequences (1, 3, 7, 8), (1, 2, 7, 8), (1, 2, 3, 8), for which the difficulty is 4, 5 and 5, respectively. Thus, after removing the second element we obtain the optimal answer — 4.
|
```python
n = int(input())
a = list(map(int, input(). split()))
sl = []; s2 = []
for i in range(n - 2):
sl += [a[i + 2] - a[i]]
s2 += [a[i + 1] - a[i]]
s2 += [a[-1] - a[-2]]
print(max(min(sl), max(s2)))
```
| 3
|
|
977
|
A
|
Wrong Subtraction
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Little girl Tanya is learning how to decrease a number by one, but she does it wrong with a number consisting of two or more digits. Tanya subtracts one from a number by the following algorithm:
- if the last digit of the number is non-zero, she decreases the number by one; - if the last digit of the number is zero, she divides the number by 10 (i.e. removes the last digit).
You are given an integer number $n$. Tanya will subtract one from it $k$ times. Your task is to print the result after all $k$ subtractions.
It is guaranteed that the result will be positive integer number.
|
The first line of the input contains two integer numbers $n$ and $k$ ($2 \le n \le 10^9$, $1 \le k \le 50$) — the number from which Tanya will subtract and the number of subtractions correspondingly.
|
Print one integer number — the result of the decreasing $n$ by one $k$ times.
It is guaranteed that the result will be positive integer number.
|
[
"512 4\n",
"1000000000 9\n"
] |
[
"50\n",
"1\n"
] |
The first example corresponds to the following sequence: $512 \rightarrow 511 \rightarrow 510 \rightarrow 51 \rightarrow 50$.
| 0
|
[
{
"input": "512 4",
"output": "50"
},
{
"input": "1000000000 9",
"output": "1"
},
{
"input": "131203 11",
"output": "12"
},
{
"input": "999999999 50",
"output": "9999"
},
{
"input": "999999999 49",
"output": "99990"
},
{
"input": "131203 9",
"output": "130"
},
{
"input": "900000000 16",
"output": "1"
},
{
"input": "909090909 50",
"output": "3"
},
{
"input": "1001 2",
"output": "100"
},
{
"input": "5 2",
"output": "3"
},
{
"input": "2 1",
"output": "1"
}
] | 1,699,472,000
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 11
| 31
| 0
|
a,b = map(int, input().split())
for i in range(b):
if a%10==0:
a=a/10
else:
a-=1
print(int(a))
|
Title: Wrong Subtraction
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Little girl Tanya is learning how to decrease a number by one, but she does it wrong with a number consisting of two or more digits. Tanya subtracts one from a number by the following algorithm:
- if the last digit of the number is non-zero, she decreases the number by one; - if the last digit of the number is zero, she divides the number by 10 (i.e. removes the last digit).
You are given an integer number $n$. Tanya will subtract one from it $k$ times. Your task is to print the result after all $k$ subtractions.
It is guaranteed that the result will be positive integer number.
Input Specification:
The first line of the input contains two integer numbers $n$ and $k$ ($2 \le n \le 10^9$, $1 \le k \le 50$) — the number from which Tanya will subtract and the number of subtractions correspondingly.
Output Specification:
Print one integer number — the result of the decreasing $n$ by one $k$ times.
It is guaranteed that the result will be positive integer number.
Demo Input:
['512 4\n', '1000000000 9\n']
Demo Output:
['50\n', '1\n']
Note:
The first example corresponds to the following sequence: $512 \rightarrow 511 \rightarrow 510 \rightarrow 51 \rightarrow 50$.
|
```python
a,b = map(int, input().split())
for i in range(b):
if a%10==0:
a=a/10
else:
a-=1
print(int(a))
```
| 3
|
|
427
|
A
|
Police Recruits
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
The police department of your city has just started its journey. Initially, they don’t have any manpower. So, they started hiring new recruits in groups.
Meanwhile, crimes keeps occurring within the city. One member of the police force can investigate only one crime during his/her lifetime.
If there is no police officer free (isn't busy with crime) during the occurrence of a crime, it will go untreated.
Given the chronological order of crime occurrences and recruit hirings, find the number of crimes which will go untreated.
|
The first line of input will contain an integer *n* (1<=≤<=*n*<=≤<=105), the number of events. The next line will contain *n* space-separated integers.
If the integer is -1 then it means a crime has occurred. Otherwise, the integer will be positive, the number of officers recruited together at that time. No more than 10 officers will be recruited at a time.
|
Print a single integer, the number of crimes which will go untreated.
|
[
"3\n-1 -1 1\n",
"8\n1 -1 1 -1 -1 1 1 1\n",
"11\n-1 -1 2 -1 -1 -1 -1 -1 -1 -1 -1\n"
] |
[
"2\n",
"1\n",
"8\n"
] |
Lets consider the second example:
1. Firstly one person is hired. 1. Then crime appears, the last hired person will investigate this crime. 1. One more person is hired. 1. One more crime appears, the last hired person will investigate this crime. 1. Crime appears. There is no free policeman at the time, so this crime will go untreated. 1. One more person is hired. 1. One more person is hired. 1. One more person is hired.
The answer is one, as one crime (on step 5) will go untreated.
| 500
|
[
{
"input": "3\n-1 -1 1",
"output": "2"
},
{
"input": "8\n1 -1 1 -1 -1 1 1 1",
"output": "1"
},
{
"input": "11\n-1 -1 2 -1 -1 -1 -1 -1 -1 -1 -1",
"output": "8"
},
{
"input": "7\n-1 -1 1 1 -1 -1 1",
"output": "2"
},
{
"input": "21\n-1 -1 -1 -1 -1 3 2 -1 6 -1 -1 2 1 -1 2 2 1 6 5 -1 5",
"output": "5"
},
{
"input": "98\n-1 -1 1 -1 -1 -1 -1 1 -1 -1 1 -1 -1 1 -1 1 1 1 -1 1 1 1 1 1 -1 1 -1 -1 -1 -1 1 -1 -1 1 1 -1 1 1 1 -1 -1 -1 -1 -1 -1 1 -1 -1 -1 1 -1 1 -1 1 -1 1 1 1 1 1 1 1 -1 -1 1 1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 -1 1 -1 1 1 1 -1 1 1 -1 -1 -1 1 1 1 -1 -1 -1 1 -1 1 1",
"output": "13"
},
{
"input": "3\n-1 5 4",
"output": "1"
},
{
"input": "146\n4 -1 -1 -1 -1 -1 -1 -1 -1 -1 4 -1 3 -1 3 -1 -1 1 4 -1 2 -1 -1 3 -1 -1 -1 4 1 -1 -1 -1 4 -1 -1 -1 -1 -1 -1 3 2 -1 3 2 4 5 2 4 1 5 -1 -1 2 -1 -1 1 -1 5 3 -1 1 2 2 3 5 3 -1 -1 3 -1 -1 3 5 5 -1 -1 5 -1 4 4 1 -1 -1 -1 2 1 -1 -1 -1 2 5 3 -1 -1 -1 3 -1 5 4 -1 1 -1 -1 3 -1 -1 3 1 1 2 -1 -1 -1 1 3 1 -1 2 -1 -1 5 5 -1 -1 3 4 5 1 -1 2 -1 -1 -1 3 -1 5 3 2 -1 2 -1 -1 5 -1 3 -1",
"output": "5"
},
{
"input": "1\n2",
"output": "0"
},
{
"input": "1\n-1",
"output": "1"
},
{
"input": "2\n1 -1",
"output": "0"
},
{
"input": "2\n-1 1",
"output": "1"
},
{
"input": "2\n1 1",
"output": "0"
},
{
"input": "2\n-1 -1",
"output": "2"
},
{
"input": "4\n10 -1 -1 -1",
"output": "0"
},
{
"input": "1\n1",
"output": "0"
},
{
"input": "4\n-1 -1 1 1",
"output": "2"
}
] | 1,683,663,203
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 63
| 62
| 10,547,200
|
NumberOfEvents = int(input())
events = list(map(int, input().split()))
police = 0
untreated = 0
for i in range(NumberOfEvents):
if events[i] > 0:
police += events[i]
elif events[i] == -1 and police > 0:
police -= 1
else:
untreated += 1
print(untreated)
|
Title: Police Recruits
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The police department of your city has just started its journey. Initially, they don’t have any manpower. So, they started hiring new recruits in groups.
Meanwhile, crimes keeps occurring within the city. One member of the police force can investigate only one crime during his/her lifetime.
If there is no police officer free (isn't busy with crime) during the occurrence of a crime, it will go untreated.
Given the chronological order of crime occurrences and recruit hirings, find the number of crimes which will go untreated.
Input Specification:
The first line of input will contain an integer *n* (1<=≤<=*n*<=≤<=105), the number of events. The next line will contain *n* space-separated integers.
If the integer is -1 then it means a crime has occurred. Otherwise, the integer will be positive, the number of officers recruited together at that time. No more than 10 officers will be recruited at a time.
Output Specification:
Print a single integer, the number of crimes which will go untreated.
Demo Input:
['3\n-1 -1 1\n', '8\n1 -1 1 -1 -1 1 1 1\n', '11\n-1 -1 2 -1 -1 -1 -1 -1 -1 -1 -1\n']
Demo Output:
['2\n', '1\n', '8\n']
Note:
Lets consider the second example:
1. Firstly one person is hired. 1. Then crime appears, the last hired person will investigate this crime. 1. One more person is hired. 1. One more crime appears, the last hired person will investigate this crime. 1. Crime appears. There is no free policeman at the time, so this crime will go untreated. 1. One more person is hired. 1. One more person is hired. 1. One more person is hired.
The answer is one, as one crime (on step 5) will go untreated.
|
```python
NumberOfEvents = int(input())
events = list(map(int, input().split()))
police = 0
untreated = 0
for i in range(NumberOfEvents):
if events[i] > 0:
police += events[i]
elif events[i] == -1 and police > 0:
police -= 1
else:
untreated += 1
print(untreated)
```
| 3
|
|
546
|
A
|
Soldier and Bananas
|
PROGRAMMING
| 800
|
[
"brute force",
"implementation",
"math"
] | null | null |
A soldier wants to buy *w* bananas in the shop. He has to pay *k* dollars for the first banana, 2*k* dollars for the second one and so on (in other words, he has to pay *i*·*k* dollars for the *i*-th banana).
He has *n* dollars. How many dollars does he have to borrow from his friend soldier to buy *w* bananas?
|
The first line contains three positive integers *k*,<=*n*,<=*w* (1<=<=≤<=<=*k*,<=*w*<=<=≤<=<=1000, 0<=≤<=*n*<=≤<=109), the cost of the first banana, initial number of dollars the soldier has and number of bananas he wants.
|
Output one integer — the amount of dollars that the soldier must borrow from his friend. If he doesn't have to borrow money, output 0.
|
[
"3 17 4\n"
] |
[
"13"
] |
none
| 500
|
[
{
"input": "3 17 4",
"output": "13"
},
{
"input": "1 2 1",
"output": "0"
},
{
"input": "1 1 1",
"output": "0"
},
{
"input": "1 5 6",
"output": "16"
},
{
"input": "1 1000000000 1",
"output": "0"
},
{
"input": "1000 0 1000",
"output": "500500000"
},
{
"input": "859 453892 543",
"output": "126416972"
},
{
"input": "1000 1000000000 1000",
"output": "0"
},
{
"input": "1000 500500000 1000",
"output": "0"
},
{
"input": "1000 500500001 1000",
"output": "0"
},
{
"input": "1000 500499999 1000",
"output": "1"
},
{
"input": "634 87973 214",
"output": "14497197"
},
{
"input": "432 10000 241",
"output": "12587552"
},
{
"input": "111 111111111 111",
"output": "0"
},
{
"input": "20 43 3",
"output": "77"
}
] | 1,694,669,192
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 15
| 31
| 0
|
a=input().split()
if int(a[1])>=int(a[0])*(1+int(a[2]))*int(a[2])/2:
print("0")
else:
print(int(int(a[0])*(1+int(a[2]))*int(a[2])/2-int(a[1])))
|
Title: Soldier and Bananas
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A soldier wants to buy *w* bananas in the shop. He has to pay *k* dollars for the first banana, 2*k* dollars for the second one and so on (in other words, he has to pay *i*·*k* dollars for the *i*-th banana).
He has *n* dollars. How many dollars does he have to borrow from his friend soldier to buy *w* bananas?
Input Specification:
The first line contains three positive integers *k*,<=*n*,<=*w* (1<=<=≤<=<=*k*,<=*w*<=<=≤<=<=1000, 0<=≤<=*n*<=≤<=109), the cost of the first banana, initial number of dollars the soldier has and number of bananas he wants.
Output Specification:
Output one integer — the amount of dollars that the soldier must borrow from his friend. If he doesn't have to borrow money, output 0.
Demo Input:
['3 17 4\n']
Demo Output:
['13']
Note:
none
|
```python
a=input().split()
if int(a[1])>=int(a[0])*(1+int(a[2]))*int(a[2])/2:
print("0")
else:
print(int(int(a[0])*(1+int(a[2]))*int(a[2])/2-int(a[1])))
```
| 3
|
|
709
|
B
|
Checkpoints
|
PROGRAMMING
| 1,500
|
[
"greedy",
"implementation",
"sortings"
] | null | null |
Vasya takes part in the orienteering competition. There are *n* checkpoints located along the line at coordinates *x*1,<=*x*2,<=...,<=*x**n*. Vasya starts at the point with coordinate *a*. His goal is to visit at least *n*<=-<=1 checkpoint in order to finish the competition. Participant are allowed to visit checkpoints in arbitrary order.
Vasya wants to pick such checkpoints and the order of visiting them that the total distance travelled is minimized. He asks you to calculate this minimum possible value.
|
The first line of the input contains two integers *n* and *a* (1<=≤<=*n*<=≤<=100<=000, <=-<=1<=000<=000<=≤<=*a*<=≤<=1<=000<=000) — the number of checkpoints and Vasya's starting position respectively.
The second line contains *n* integers *x*1,<=*x*2,<=...,<=*x**n* (<=-<=1<=000<=000<=≤<=*x**i*<=≤<=1<=000<=000) — coordinates of the checkpoints.
|
Print one integer — the minimum distance Vasya has to travel in order to visit at least *n*<=-<=1 checkpoint.
|
[
"3 10\n1 7 12\n",
"2 0\n11 -10\n",
"5 0\n0 0 1000 0 0\n"
] |
[
"7\n",
"10\n",
"0\n"
] |
In the first sample Vasya has to visit at least two checkpoints. The optimal way to achieve this is the walk to the third checkpoints (distance is 12 - 10 = 2) and then proceed to the second one (distance is 12 - 7 = 5). The total distance is equal to 2 + 5 = 7.
In the second sample it's enough to visit only one checkpoint so Vasya should just walk to the point - 10.
| 1,000
|
[
{
"input": "3 10\n1 7 12",
"output": "7"
},
{
"input": "2 0\n11 -10",
"output": "10"
},
{
"input": "5 0\n0 0 1000 0 0",
"output": "0"
},
{
"input": "1 0\n0",
"output": "0"
},
{
"input": "2 1\n4 -8",
"output": "3"
},
{
"input": "3 4\n4 2 4",
"output": "0"
},
{
"input": "4 7\n8 -4 -10 6",
"output": "13"
},
{
"input": "5 7\n8 3 1 6 4",
"output": "6"
},
{
"input": "6 -9\n-10 -7 4 -7 0 3",
"output": "13"
},
{
"input": "9 -3\n-10 -7 -3 -4 7 -6 10 -10 -7",
"output": "24"
},
{
"input": "18 8\n19 18 20 11 16 12 20 17 15 11 16 13 20 13 14 16 10 12",
"output": "12"
},
{
"input": "26 3\n20 15 19 20 17 10 15 20 16 14 19 12 18 15 14 16 13 13 20 12 12 13 12 18 15 11",
"output": "17"
},
{
"input": "40 4\n10 13 15 17 13 12 16 20 14 17 11 11 18 12 18 19 19 16 13 13 12 15 14 12 10 15 16 11 13 12 12 15 10 17 13 10 12 19 14 15",
"output": "15"
},
{
"input": "44 4\n11 15 10 19 14 13 14 11 11 13 13 14 15 17 18 19 11 13 14 17 12 16 19 19 13 20 14 12 13 14 12 13 14 14 10 20 17 16 12 11 14 19 11 12",
"output": "16"
},
{
"input": "51 5\n20 20 10 17 11 15 12 11 12 19 17 12 16 11 18 11 14 16 11 19 13 13 20 14 18 13 20 18 13 15 12 12 10 11 13 19 12 11 14 17 14 19 18 18 14 13 10 12 16 18 20",
"output": "15"
},
{
"input": "65 13\n14 10 16 19 12 12 10 14 20 11 12 11 17 12 11 14 20 20 16 12 17 14 11 20 10 11 10 13 10 20 19 14 14 11 10 18 10 18 13 10 20 20 10 13 16 10 12 10 12 17 16 18 10 10 12 16 10 13 15 20 13 12 19 20 16",
"output": "13"
},
{
"input": "73 14\n11 19 16 17 10 14 15 13 19 15 12 10 17 13 11 17 12 20 17 10 18 18 12 12 16 15 16 19 10 14 19 16 17 18 17 18 16 20 18 16 19 20 20 20 18 19 11 12 11 15 13 16 12 18 11 20 19 10 19 16 14 11 18 14 13 19 16 11 11 10 12 16 18",
"output": "14"
},
{
"input": "87 1\n16 10 11 15 11 16 16 16 16 14 14 12 14 10 18 10 18 13 18 11 11 19 13 11 19 17 14 20 10 12 16 15 18 16 19 13 10 19 10 15 11 17 13 16 13 15 13 10 12 13 20 10 18 19 11 20 14 14 12 14 17 10 15 11 17 13 16 19 12 10 14 15 20 10 17 14 19 11 20 10 17 15 20 12 10 14 14",
"output": "19"
},
{
"input": "91 25\n19 15 20 12 18 11 18 12 20 11 16 18 13 11 11 13 13 14 15 16 13 11 13 19 15 13 10 15 10 12 13 11 18 11 14 10 11 11 20 14 11 11 14 10 14 19 13 16 19 12 18 18 14 15 10 14 16 11 11 14 12 14 14 20 16 15 17 17 12 15 12 15 20 16 10 18 15 15 19 18 19 18 12 10 11 15 20 20 15 16 15",
"output": "15"
},
{
"input": "11 -28\n-20 -18 -12 -11 -13 -14 -13 -17 -14 -10 -10",
"output": "18"
},
{
"input": "28 -20\n-11 -16 -16 -18 -15 -12 -18 -13 -19 -20 -19 -20 -18 -15 -18 -15 -11 -10 -20 -17 -15 -14 -16 -13 -10 -16 -20 -17",
"output": "10"
},
{
"input": "38 -29\n-13 -13 -10 -12 -13 -13 -13 -18 -18 -20 -19 -14 -17 -16 -19 -13 -10 -14 -19 -12 -16 -17 -11 -12 -12 -13 -18 -12 -11 -18 -15 -20 -20 -14 -13 -17 -12 -12",
"output": "19"
},
{
"input": "45 -21\n-19 -13 -10 -16 -15 -18 -18 -18 -13 -19 -19 -15 -17 -17 -16 -16 -11 -19 -20 -12 -17 -12 -16 -18 -10 -17 -12 -18 -15 -20 -10 -16 -20 -17 -11 -18 -20 -10 -19 -11 -16 -18 -15 -16 -18",
"output": "11"
},
{
"input": "59 -3\n-12 -15 -17 -12 -14 -13 -20 -15 -18 -19 -12 -16 -20 -17 -10 -15 -18 -12 -20 -20 -14 -15 -11 -13 -20 -19 -14 -16 -19 -15 -16 -12 -20 -12 -15 -16 -12 -19 -13 -16 -13 -17 -15 -13 -10 -13 -17 -17 -13 -13 -14 -12 -13 -18 -17 -18 -15 -14 -15",
"output": "17"
},
{
"input": "61 -27\n-14 -15 -11 -20 -13 -15 -14 -19 -17 -18 -16 -11 -16 -18 -11 -17 -13 -17 -13 -19 -15 -14 -14 -12 -19 -16 -13 -15 -13 -20 -18 -15 -17 -14 -13 -10 -20 -17 -10 -13 -16 -12 -11 -19 -15 -10 -13 -13 -15 -20 -13 -15 -18 -11 -13 -19 -13 -17 -11 -16 -12",
"output": "17"
},
{
"input": "76 -20\n-20 -12 -19 -13 -14 -19 -19 -19 -12 -17 -12 -16 -19 -19 -19 -16 -10 -18 -16 -19 -16 -10 -16 -11 -18 -13 -11 -10 -13 -11 -13 -10 -18 -20 -13 -15 -13 -19 -15 -18 -20 -10 -11 -20 -10 -11 -16 -17 -13 -12 -11 -14 -13 -16 -19 -13 -10 -11 -17 -19 -10 -10 -14 -13 -12 -15 -10 -10 -20 -20 -15 -14 -19 -18 -11 -17",
"output": "10"
},
{
"input": "89 -6\n-11 -12 -12 -20 -13 -14 -13 -13 -14 -12 -20 -20 -15 -20 -20 -19 -10 -19 -13 -15 -17 -20 -14 -19 -17 -18 -16 -19 -10 -13 -19 -10 -18 -12 -18 -13 -17 -17 -19 -18 -13 -20 -19 -10 -15 -15 -12 -20 -14 -20 -14 -17 -18 -13 -15 -14 -10 -14 -20 -13 -16 -10 -20 -18 -15 -15 -15 -16 -19 -13 -15 -18 -18 -11 -13 -19 -18 -20 -12 -13 -11 -14 -10 -10 -14 -15 -15 -12 -13",
"output": "14"
},
{
"input": "97 -13\n-17 -11 -20 -16 -11 -18 -17 -14 -19 -13 -11 -19 -15 -17 -11 -20 -10 -19 -10 -18 -11 -14 -11 -15 -13 -13 -11 -18 -18 -18 -11 -14 -20 -19 -10 -17 -18 -19 -17 -11 -11 -11 -20 -19 -16 -15 -18 -15 -15 -20 -19 -20 -16 -13 -17 -11 -13 -18 -10 -13 -10 -14 -12 -17 -20 -10 -11 -19 -19 -15 -19 -10 -18 -14 -15 -15 -11 -13 -20 -10 -10 -16 -18 -15 -14 -13 -13 -11 -16 -10 -16 -18 -11 -19 -11 -14 -18",
"output": "13"
},
{
"input": "1 -42\n-100",
"output": "0"
},
{
"input": "1 1000000\n-1000000",
"output": "0"
},
{
"input": "1 -1000000\n1000000",
"output": "0"
},
{
"input": "1 89765\n89782",
"output": "0"
},
{
"input": "1 -78621\n-77777",
"output": "0"
},
{
"input": "5 10\n1 1 1 1 1",
"output": "9"
},
{
"input": "1 5\n0",
"output": "0"
},
{
"input": "1 100\n300",
"output": "0"
},
{
"input": "2 2\n2 2",
"output": "0"
},
{
"input": "1 10\n1",
"output": "0"
},
{
"input": "1 10\n7",
"output": "0"
},
{
"input": "1 100\n1",
"output": "0"
},
{
"input": "1 5\n-1",
"output": "0"
},
{
"input": "5 3\n-100000 1 1 2 10",
"output": "11"
},
{
"input": "3 1000\n0 1001 4004",
"output": "1002"
},
{
"input": "6 51\n0 50 50 50 50 60",
"output": "11"
},
{
"input": "6 4\n-100 1 2 3 4 5",
"output": "5"
},
{
"input": "1 7\n7",
"output": "0"
},
{
"input": "6 -2\n-3 1 2 3 4 6",
"output": "8"
},
{
"input": "5 6\n-1000000 2 3 4 1000",
"output": "1002"
}
] | 1,689,448,680
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 0
| 46
| 0
|
print("_RANDOM_GUESS_1689448680.4300232")# 1689448680.430042
|
Title: Checkpoints
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya takes part in the orienteering competition. There are *n* checkpoints located along the line at coordinates *x*1,<=*x*2,<=...,<=*x**n*. Vasya starts at the point with coordinate *a*. His goal is to visit at least *n*<=-<=1 checkpoint in order to finish the competition. Participant are allowed to visit checkpoints in arbitrary order.
Vasya wants to pick such checkpoints and the order of visiting them that the total distance travelled is minimized. He asks you to calculate this minimum possible value.
Input Specification:
The first line of the input contains two integers *n* and *a* (1<=≤<=*n*<=≤<=100<=000, <=-<=1<=000<=000<=≤<=*a*<=≤<=1<=000<=000) — the number of checkpoints and Vasya's starting position respectively.
The second line contains *n* integers *x*1,<=*x*2,<=...,<=*x**n* (<=-<=1<=000<=000<=≤<=*x**i*<=≤<=1<=000<=000) — coordinates of the checkpoints.
Output Specification:
Print one integer — the minimum distance Vasya has to travel in order to visit at least *n*<=-<=1 checkpoint.
Demo Input:
['3 10\n1 7 12\n', '2 0\n11 -10\n', '5 0\n0 0 1000 0 0\n']
Demo Output:
['7\n', '10\n', '0\n']
Note:
In the first sample Vasya has to visit at least two checkpoints. The optimal way to achieve this is the walk to the third checkpoints (distance is 12 - 10 = 2) and then proceed to the second one (distance is 12 - 7 = 5). The total distance is equal to 2 + 5 = 7.
In the second sample it's enough to visit only one checkpoint so Vasya should just walk to the point - 10.
|
```python
print("_RANDOM_GUESS_1689448680.4300232")# 1689448680.430042
```
| 0
|
|
983
|
A
|
Finite or not?
|
PROGRAMMING
| 1,700
|
[
"implementation",
"math"
] | null | null |
You are given several queries. Each query consists of three integers $p$, $q$ and $b$. You need to answer whether the result of $p/q$ in notation with base $b$ is a finite fraction.
A fraction in notation with base $b$ is finite if it contains finite number of numerals after the decimal point. It is also possible that a fraction has zero numerals after the decimal point.
|
The first line contains a single integer $n$ ($1 \le n \le 10^5$) — the number of queries.
Next $n$ lines contain queries, one per line. Each line contains three integers $p$, $q$, and $b$ ($0 \le p \le 10^{18}$, $1 \le q \le 10^{18}$, $2 \le b \le 10^{18}$). All numbers are given in notation with base $10$.
|
For each question, in a separate line, print Finite if the fraction is finite and Infinite otherwise.
|
[
"2\n6 12 10\n4 3 10\n",
"4\n1 1 2\n9 36 2\n4 12 3\n3 5 4\n"
] |
[
"Finite\nInfinite\n",
"Finite\nFinite\nFinite\nInfinite\n"
] |
$\frac{6}{12} = \frac{1}{2} = 0,5_{10}$
$\frac{4}{3} = 1,(3)_{10}$
$\frac{9}{36} = \frac{1}{4} = 0,01_2$
$\frac{4}{12} = \frac{1}{3} = 0,1_3$
| 500
|
[
{
"input": "2\n6 12 10\n4 3 10",
"output": "Finite\nInfinite"
},
{
"input": "4\n1 1 2\n9 36 2\n4 12 3\n3 5 4",
"output": "Finite\nFinite\nFinite\nInfinite"
},
{
"input": "10\n10 5 3\n1 7 10\n7 5 7\n4 4 9\n6 5 2\n6 7 5\n9 9 7\n7 5 5\n6 6 4\n10 8 2",
"output": "Finite\nInfinite\nInfinite\nFinite\nInfinite\nInfinite\nFinite\nFinite\nFinite\nFinite"
},
{
"input": "10\n1 3 10\n6 2 6\n2 3 9\n7 8 4\n5 6 10\n1 2 7\n0 3 6\n9 3 4\n4 4 9\n10 9 10",
"output": "Infinite\nFinite\nFinite\nFinite\nInfinite\nInfinite\nFinite\nFinite\nFinite\nInfinite"
},
{
"input": "10\n10 8 5\n0 6 9\n0 7 6\n5 7 3\n7 6 8\n0 4 8\n2 6 3\n10 2 9\n6 7 9\n9 1 4",
"output": "Infinite\nFinite\nFinite\nInfinite\nInfinite\nFinite\nFinite\nFinite\nInfinite\nFinite"
},
{
"input": "10\n5 8 2\n0 5 8\n5 9 7\n0 7 2\n6 7 2\n10 3 7\n8 1 10\n9 1 8\n0 7 10\n9 1 4",
"output": "Finite\nFinite\nInfinite\nFinite\nInfinite\nInfinite\nFinite\nFinite\nFinite\nFinite"
},
{
"input": "1\n1 864691128455135232 2",
"output": "Infinite"
},
{
"input": "11\n1 1000000000000000000 10000000\n2 999 9\n2 999 333111\n0 9 7\n17 128 2\n13 311992186885373952 18\n1971402979058461 750473176484995605 75\n14 19 23\n3 21914624432020321 23\n3 21914624432020321 46\n3 21914624432020321 47",
"output": "Finite\nInfinite\nFinite\nFinite\nFinite\nFinite\nFinite\nInfinite\nFinite\nFinite\nInfinite"
},
{
"input": "1\n1 100000000000000000 10000000000000000",
"output": "Finite"
},
{
"input": "1\n1 4294967297 4294967296",
"output": "Infinite"
},
{
"input": "1\n1 5244319080000 30030",
"output": "Finite"
}
] | 1,540,257,086
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 1
| 155
| 1,024,000
|
import fractions
q = int(input())
for i in range(0,q):
arr = input().split()
for j in range(0,3):
arr[j] = int(arr[j])
a = arr[0]
b = arr[1]
c = arr[2]
a = a%c
b = b%c
if fractions.gcd(a,b) == 1:
print("Infinite")
else:
print("Finite")
|
Title: Finite or not?
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given several queries. Each query consists of three integers $p$, $q$ and $b$. You need to answer whether the result of $p/q$ in notation with base $b$ is a finite fraction.
A fraction in notation with base $b$ is finite if it contains finite number of numerals after the decimal point. It is also possible that a fraction has zero numerals after the decimal point.
Input Specification:
The first line contains a single integer $n$ ($1 \le n \le 10^5$) — the number of queries.
Next $n$ lines contain queries, one per line. Each line contains three integers $p$, $q$, and $b$ ($0 \le p \le 10^{18}$, $1 \le q \le 10^{18}$, $2 \le b \le 10^{18}$). All numbers are given in notation with base $10$.
Output Specification:
For each question, in a separate line, print Finite if the fraction is finite and Infinite otherwise.
Demo Input:
['2\n6 12 10\n4 3 10\n', '4\n1 1 2\n9 36 2\n4 12 3\n3 5 4\n']
Demo Output:
['Finite\nInfinite\n', 'Finite\nFinite\nFinite\nInfinite\n']
Note:
$\frac{6}{12} = \frac{1}{2} = 0,5_{10}$
$\frac{4}{3} = 1,(3)_{10}$
$\frac{9}{36} = \frac{1}{4} = 0,01_2$
$\frac{4}{12} = \frac{1}{3} = 0,1_3$
|
```python
import fractions
q = int(input())
for i in range(0,q):
arr = input().split()
for j in range(0,3):
arr[j] = int(arr[j])
a = arr[0]
b = arr[1]
c = arr[2]
a = a%c
b = b%c
if fractions.gcd(a,b) == 1:
print("Infinite")
else:
print("Finite")
```
| 0
|
|
165
|
B
|
Burning Midnight Oil
|
PROGRAMMING
| 1,500
|
[
"binary search",
"implementation"
] | null | null |
One day a highly important task was commissioned to Vasya — writing a program in a night. The program consists of *n* lines of code. Vasya is already exhausted, so he works like that: first he writes *v* lines of code, drinks a cup of tea, then he writes as much as lines, drinks another cup of tea, then he writes lines and so on: , , , ...
The expression is regarded as the integral part from dividing number *a* by number *b*.
The moment the current value equals 0, Vasya immediately falls asleep and he wakes up only in the morning, when the program should already be finished.
Vasya is wondering, what minimum allowable value *v* can take to let him write not less than *n* lines of code before he falls asleep.
|
The input consists of two integers *n* and *k*, separated by spaces — the size of the program in lines and the productivity reduction coefficient, 1<=≤<=*n*<=≤<=109, 2<=≤<=*k*<=≤<=10.
|
Print the only integer — the minimum value of *v* that lets Vasya write the program in one night.
|
[
"7 2\n",
"59 9\n"
] |
[
"4\n",
"54\n"
] |
In the first sample the answer is *v* = 4. Vasya writes the code in the following portions: first 4 lines, then 2, then 1, and then Vasya falls asleep. Thus, he manages to write 4 + 2 + 1 = 7 lines in a night and complete the task.
In the second sample the answer is *v* = 54. Vasya writes the code in the following portions: 54, 6. The total sum is 54 + 6 = 60, that's even more than *n* = 59.
| 1,000
|
[
{
"input": "7 2",
"output": "4"
},
{
"input": "59 9",
"output": "54"
},
{
"input": "1 9",
"output": "1"
},
{
"input": "11 2",
"output": "7"
},
{
"input": "747 2",
"output": "376"
},
{
"input": "6578 2",
"output": "3293"
},
{
"input": "37212 2",
"output": "18609"
},
{
"input": "12357 2",
"output": "6181"
},
{
"input": "7998332 2",
"output": "3999172"
},
{
"input": "86275251 2",
"output": "43137632"
},
{
"input": "75584551 2",
"output": "37792280"
},
{
"input": "6 3",
"output": "5"
},
{
"input": "43 4",
"output": "33"
},
{
"input": "811 3",
"output": "543"
},
{
"input": "3410 4",
"output": "2560"
},
{
"input": "21341 4",
"output": "16009"
},
{
"input": "696485 4",
"output": "522368"
},
{
"input": "8856748 3",
"output": "5904504"
},
{
"input": "2959379 4",
"output": "2219538"
},
{
"input": "831410263 3",
"output": "554273516"
},
{
"input": "2 5",
"output": "2"
},
{
"input": "19 6",
"output": "17"
},
{
"input": "715 7",
"output": "615"
},
{
"input": "9122 5",
"output": "7300"
},
{
"input": "89117 6",
"output": "74268"
},
{
"input": "689973 7",
"output": "591408"
},
{
"input": "3024524 5",
"output": "2419624"
},
{
"input": "67127156 6",
"output": "55939302"
},
{
"input": "412262167 7",
"output": "353367574"
},
{
"input": "6 8",
"output": "6"
},
{
"input": "59 9",
"output": "54"
},
{
"input": "246 10",
"output": "222"
},
{
"input": "5314 8",
"output": "4651"
},
{
"input": "15309 9",
"output": "13609"
},
{
"input": "35648 10",
"output": "32085"
},
{
"input": "3018012 8",
"output": "2640764"
},
{
"input": "92153348 9",
"output": "81914089"
},
{
"input": "177583558 10",
"output": "159825206"
},
{
"input": "1000000000 2",
"output": "500000008"
},
{
"input": "1000000000 3",
"output": "666666672"
},
{
"input": "1000000000 4",
"output": "750000005"
},
{
"input": "1000000000 5",
"output": "800000003"
},
{
"input": "1000000000 6",
"output": "833333338"
},
{
"input": "1000000000 7",
"output": "857142861"
},
{
"input": "1000000000 8",
"output": "875000004"
},
{
"input": "1000000000 9",
"output": "888888894"
},
{
"input": "1000000000 10",
"output": "900000001"
},
{
"input": "1 4",
"output": "1"
},
{
"input": "2 10",
"output": "2"
},
{
"input": "1 2",
"output": "1"
},
{
"input": "6 8",
"output": "6"
},
{
"input": "987862820 9",
"output": "878100288"
},
{
"input": "979591791 9",
"output": "870748262"
},
{
"input": "948889213 9",
"output": "843457081"
},
{
"input": "8 9",
"output": "8"
},
{
"input": "999999999 10",
"output": "900000000"
}
] | 1,691,045,069
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 56
| 124
| 0
|
def coding(v,k):
i = 1
ans = v
while k ** i <= v:
ans += v // (k ** i)
i += 1
return ans
n, k = list(map(int,input().split()))
start = n - n//k
while coding(start,k) < n:
start += 1
print(start)
|
Title: Burning Midnight Oil
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day a highly important task was commissioned to Vasya — writing a program in a night. The program consists of *n* lines of code. Vasya is already exhausted, so he works like that: first he writes *v* lines of code, drinks a cup of tea, then he writes as much as lines, drinks another cup of tea, then he writes lines and so on: , , , ...
The expression is regarded as the integral part from dividing number *a* by number *b*.
The moment the current value equals 0, Vasya immediately falls asleep and he wakes up only in the morning, when the program should already be finished.
Vasya is wondering, what minimum allowable value *v* can take to let him write not less than *n* lines of code before he falls asleep.
Input Specification:
The input consists of two integers *n* and *k*, separated by spaces — the size of the program in lines and the productivity reduction coefficient, 1<=≤<=*n*<=≤<=109, 2<=≤<=*k*<=≤<=10.
Output Specification:
Print the only integer — the minimum value of *v* that lets Vasya write the program in one night.
Demo Input:
['7 2\n', '59 9\n']
Demo Output:
['4\n', '54\n']
Note:
In the first sample the answer is *v* = 4. Vasya writes the code in the following portions: first 4 lines, then 2, then 1, and then Vasya falls asleep. Thus, he manages to write 4 + 2 + 1 = 7 lines in a night and complete the task.
In the second sample the answer is *v* = 54. Vasya writes the code in the following portions: 54, 6. The total sum is 54 + 6 = 60, that's even more than *n* = 59.
|
```python
def coding(v,k):
i = 1
ans = v
while k ** i <= v:
ans += v // (k ** i)
i += 1
return ans
n, k = list(map(int,input().split()))
start = n - n//k
while coding(start,k) < n:
start += 1
print(start)
```
| 3
|
|
628
|
C
|
Bear and String Distance
|
PROGRAMMING
| 1,300
|
[
"greedy",
"strings"
] | null | null |
Limak is a little polar bear. He likes nice strings — strings of length *n*, consisting of lowercase English letters only.
The distance between two letters is defined as the difference between their positions in the alphabet. For example, , and .
Also, the distance between two nice strings is defined as the sum of distances of corresponding letters. For example, , and .
Limak gives you a nice string *s* and an integer *k*. He challenges you to find any nice string *s*' that . Find any *s*' satisfying the given conditions, or print "-1" if it's impossible to do so.
As input/output can reach huge size it is recommended to use fast input/output methods: for example, prefer to use gets/scanf/printf instead of getline/cin/cout in C++, prefer to use BufferedReader/PrintWriter instead of Scanner/System.out in Java.
|
The first line contains two integers *n* and *k* (1<=≤<=*n*<=≤<=105, 0<=≤<=*k*<=≤<=106).
The second line contains a string *s* of length *n*, consisting of lowercase English letters.
|
If there is no string satisfying the given conditions then print "-1" (without the quotes).
Otherwise, print any nice string *s*' that .
|
[
"4 26\nbear\n",
"2 7\naf\n",
"3 1000\nhey\n"
] |
[
"roar",
"db\n",
"-1\n"
] |
none
| 0
|
[
{
"input": "4 26\nbear",
"output": "zcar"
},
{
"input": "2 7\naf",
"output": "hf"
},
{
"input": "3 1000\nhey",
"output": "-1"
},
{
"input": "5 50\nkzsij",
"output": "zaiij"
},
{
"input": "5 500\nvsdxg",
"output": "-1"
},
{
"input": "1 0\na",
"output": "a"
},
{
"input": "1 1\ng",
"output": "f"
},
{
"input": "1 25\nr",
"output": "-1"
},
{
"input": "1 15\no",
"output": "-1"
},
{
"input": "10 100\naddaiyssyp",
"output": "zzzzcyssyp"
},
{
"input": "50 100\ntewducenaqgpilgftjcmzttrgebnyldwfgbtttrygaiqtkgbjb",
"output": "azazecenaqgpilgftjcmzttrgebnyldwfgbtttrygaiqtkgbjb"
},
{
"input": "2 1\nzz",
"output": "yz"
},
{
"input": "8 8\nabcdefgh",
"output": "ibcdefgh"
},
{
"input": "1 25\nz",
"output": "a"
},
{
"input": "1 24\nz",
"output": "b"
},
{
"input": "1 24\ny",
"output": "a"
},
{
"input": "2 49\nzz",
"output": "ab"
},
{
"input": "1 26\na",
"output": "-1"
},
{
"input": "1 25\na",
"output": "z"
},
{
"input": "4 17\nrzsq",
"output": "azsq"
},
{
"input": "69 1701\nzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzy",
"output": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaax"
},
{
"input": "2 9\nbc",
"output": "kc"
},
{
"input": "2 48\nab",
"output": "zy"
},
{
"input": "1 8\nc",
"output": "k"
},
{
"input": "2 25\nyd",
"output": "ac"
},
{
"input": "5 24\nizrqp",
"output": "zsrqp"
},
{
"input": "1 13\nn",
"output": "a"
},
{
"input": "5 21\nfmmqh",
"output": "zlmqh"
}
] | 1,687,558,827
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 38
| 140
| 204,800
|
s, s1 = "", ""
n, k = map(int, input().split())
s = input()
for i in range(len(s)):
dis1 = ord('z') - ord(s[i])
dis2 = ord(s[i]) - ord('a')
if dis1 > dis2:
ddd = min(dis1, k)
k -= ddd
s1 += chr(ord(s[i]) + ddd)
else:
ddd = min(dis2, k)
k -= ddd
s1 += chr(ord(s[i]) - ddd)
if k > 0:
print("-1")
else:
print(s1)
|
Title: Bear and String Distance
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Limak is a little polar bear. He likes nice strings — strings of length *n*, consisting of lowercase English letters only.
The distance between two letters is defined as the difference between their positions in the alphabet. For example, , and .
Also, the distance between two nice strings is defined as the sum of distances of corresponding letters. For example, , and .
Limak gives you a nice string *s* and an integer *k*. He challenges you to find any nice string *s*' that . Find any *s*' satisfying the given conditions, or print "-1" if it's impossible to do so.
As input/output can reach huge size it is recommended to use fast input/output methods: for example, prefer to use gets/scanf/printf instead of getline/cin/cout in C++, prefer to use BufferedReader/PrintWriter instead of Scanner/System.out in Java.
Input Specification:
The first line contains two integers *n* and *k* (1<=≤<=*n*<=≤<=105, 0<=≤<=*k*<=≤<=106).
The second line contains a string *s* of length *n*, consisting of lowercase English letters.
Output Specification:
If there is no string satisfying the given conditions then print "-1" (without the quotes).
Otherwise, print any nice string *s*' that .
Demo Input:
['4 26\nbear\n', '2 7\naf\n', '3 1000\nhey\n']
Demo Output:
['roar', 'db\n', '-1\n']
Note:
none
|
```python
s, s1 = "", ""
n, k = map(int, input().split())
s = input()
for i in range(len(s)):
dis1 = ord('z') - ord(s[i])
dis2 = ord(s[i]) - ord('a')
if dis1 > dis2:
ddd = min(dis1, k)
k -= ddd
s1 += chr(ord(s[i]) + ddd)
else:
ddd = min(dis2, k)
k -= ddd
s1 += chr(ord(s[i]) - ddd)
if k > 0:
print("-1")
else:
print(s1)
```
| 3
|
|
47
|
A
|
Triangular numbers
|
PROGRAMMING
| 800
|
[
"brute force",
"math"
] |
A. Triangular numbers
|
2
|
256
|
A triangular number is the number of dots in an equilateral triangle uniformly filled with dots. For example, three dots can be arranged in a triangle; thus three is a triangular number. The *n*-th triangular number is the number of dots in a triangle with *n* dots on a side. . You can learn more about these numbers from Wikipedia (http://en.wikipedia.org/wiki/Triangular_number).
Your task is to find out if a given integer is a triangular number.
|
The first line contains the single number *n* (1<=≤<=*n*<=≤<=500) — the given integer.
|
If the given integer is a triangular number output YES, otherwise output NO.
|
[
"1\n",
"2\n",
"3\n"
] |
[
"YES\n",
"NO\n",
"YES\n"
] |
none
| 500
|
[
{
"input": "1",
"output": "YES"
},
{
"input": "2",
"output": "NO"
},
{
"input": "3",
"output": "YES"
},
{
"input": "4",
"output": "NO"
},
{
"input": "5",
"output": "NO"
},
{
"input": "6",
"output": "YES"
},
{
"input": "7",
"output": "NO"
},
{
"input": "8",
"output": "NO"
},
{
"input": "12",
"output": "NO"
},
{
"input": "10",
"output": "YES"
},
{
"input": "11",
"output": "NO"
},
{
"input": "9",
"output": "NO"
},
{
"input": "14",
"output": "NO"
},
{
"input": "15",
"output": "YES"
},
{
"input": "16",
"output": "NO"
},
{
"input": "20",
"output": "NO"
},
{
"input": "21",
"output": "YES"
},
{
"input": "22",
"output": "NO"
},
{
"input": "121",
"output": "NO"
},
{
"input": "135",
"output": "NO"
},
{
"input": "136",
"output": "YES"
},
{
"input": "137",
"output": "NO"
},
{
"input": "152",
"output": "NO"
},
{
"input": "153",
"output": "YES"
},
{
"input": "154",
"output": "NO"
},
{
"input": "171",
"output": "YES"
},
{
"input": "189",
"output": "NO"
},
{
"input": "190",
"output": "YES"
},
{
"input": "191",
"output": "NO"
},
{
"input": "210",
"output": "YES"
},
{
"input": "211",
"output": "NO"
},
{
"input": "231",
"output": "YES"
},
{
"input": "232",
"output": "NO"
},
{
"input": "252",
"output": "NO"
},
{
"input": "253",
"output": "YES"
},
{
"input": "254",
"output": "NO"
},
{
"input": "275",
"output": "NO"
},
{
"input": "276",
"output": "YES"
},
{
"input": "277",
"output": "NO"
},
{
"input": "299",
"output": "NO"
},
{
"input": "300",
"output": "YES"
},
{
"input": "301",
"output": "NO"
},
{
"input": "324",
"output": "NO"
},
{
"input": "325",
"output": "YES"
},
{
"input": "326",
"output": "NO"
},
{
"input": "350",
"output": "NO"
},
{
"input": "351",
"output": "YES"
},
{
"input": "352",
"output": "NO"
},
{
"input": "377",
"output": "NO"
},
{
"input": "378",
"output": "YES"
},
{
"input": "406",
"output": "YES"
},
{
"input": "434",
"output": "NO"
},
{
"input": "435",
"output": "YES"
},
{
"input": "464",
"output": "NO"
},
{
"input": "465",
"output": "YES"
},
{
"input": "495",
"output": "NO"
},
{
"input": "496",
"output": "YES"
},
{
"input": "497",
"output": "NO"
},
{
"input": "331",
"output": "NO"
},
{
"input": "413",
"output": "NO"
},
{
"input": "177",
"output": "NO"
},
{
"input": "122",
"output": "NO"
},
{
"input": "478",
"output": "NO"
},
{
"input": "188",
"output": "NO"
},
{
"input": "21",
"output": "YES"
},
{
"input": "474",
"output": "NO"
},
{
"input": "21",
"output": "YES"
},
{
"input": "48",
"output": "NO"
},
{
"input": "498",
"output": "NO"
},
{
"input": "499",
"output": "NO"
},
{
"input": "500",
"output": "NO"
}
] | 1,603,205,428
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 71
| 280
| 0
|
t = int(input())
for i in range(t+1):
if(((i*(i+1))//2)==t):
print("YES")
exit()
print("NO")
|
Title: Triangular numbers
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
A triangular number is the number of dots in an equilateral triangle uniformly filled with dots. For example, three dots can be arranged in a triangle; thus three is a triangular number. The *n*-th triangular number is the number of dots in a triangle with *n* dots on a side. . You can learn more about these numbers from Wikipedia (http://en.wikipedia.org/wiki/Triangular_number).
Your task is to find out if a given integer is a triangular number.
Input Specification:
The first line contains the single number *n* (1<=≤<=*n*<=≤<=500) — the given integer.
Output Specification:
If the given integer is a triangular number output YES, otherwise output NO.
Demo Input:
['1\n', '2\n', '3\n']
Demo Output:
['YES\n', 'NO\n', 'YES\n']
Note:
none
|
```python
t = int(input())
for i in range(t+1):
if(((i*(i+1))//2)==t):
print("YES")
exit()
print("NO")
```
| 3.93
|
8
|
A
|
Train and Peter
|
PROGRAMMING
| 1,200
|
[
"strings"
] |
A. Train and Peter
|
1
|
64
|
Peter likes to travel by train. He likes it so much that on the train he falls asleep.
Once in summer Peter was going by train from city A to city B, and as usual, was sleeping. Then he woke up, started to look through the window and noticed that every railway station has a flag of a particular colour.
The boy started to memorize the order of the flags' colours that he had seen. But soon he fell asleep again. Unfortunately, he didn't sleep long, he woke up and went on memorizing the colours. Then he fell asleep again, and that time he slept till the end of the journey.
At the station he told his parents about what he was doing, and wrote two sequences of the colours that he had seen before and after his sleep, respectively.
Peter's parents know that their son likes to fantasize. They give you the list of the flags' colours at the stations that the train passes sequentially on the way from A to B, and ask you to find out if Peter could see those sequences on the way from A to B, or from B to A. Remember, please, that Peter had two periods of wakefulness.
Peter's parents put lowercase Latin letters for colours. The same letter stands for the same colour, different letters — for different colours.
|
The input data contains three lines. The first line contains a non-empty string, whose length does not exceed 105, the string consists of lowercase Latin letters — the flags' colours at the stations on the way from A to B. On the way from B to A the train passes the same stations, but in reverse order.
The second line contains the sequence, written by Peter during the first period of wakefulness. The third line contains the sequence, written during the second period of wakefulness. Both sequences are non-empty, consist of lowercase Latin letters, and the length of each does not exceed 100 letters. Each of the sequences is written in chronological order.
|
Output one of the four words without inverted commas:
- «forward» — if Peter could see such sequences only on the way from A to B; - «backward» — if Peter could see such sequences on the way from B to A; - «both» — if Peter could see such sequences both on the way from A to B, and on the way from B to A; - «fantasy» — if Peter could not see such sequences.
|
[
"atob\na\nb\n",
"aaacaaa\naca\naa\n"
] |
[
"forward\n",
"both\n"
] |
It is assumed that the train moves all the time, so one flag cannot be seen twice. There are no flags at stations A and B.
| 0
|
[
{
"input": "atob\na\nb",
"output": "forward"
},
{
"input": "aaacaaa\naca\naa",
"output": "both"
},
{
"input": "aaa\naa\naa",
"output": "fantasy"
},
{
"input": "astalavista\nastla\nlavista",
"output": "fantasy"
},
{
"input": "abacabadabacaba\nabacaba\nabacaba",
"output": "both"
},
{
"input": "a\na\na",
"output": "fantasy"
},
{
"input": "ab\nb\na",
"output": "backward"
},
{
"input": "aaa\naaaa\naaaa",
"output": "fantasy"
},
{
"input": "bbabbbbababbaabaabaa\nabb\nbaab",
"output": "forward"
},
{
"input": "bbbbbbbbbbbbbbbbbbbbbbbbb\nbbbb\nbbbbb",
"output": "both"
},
{
"input": "babaabababaaaababaabababaabababababababbababbbabbaabababaababbaabbababaababaaabababaabbaababaaababaa\nabaabababaa\nabaabbaa",
"output": "forward"
},
{
"input": "bbbbbbbbbbbbbbbbbbbbbbbbb\nbbbb\nbbbbb",
"output": "both"
},
{
"input": "aababaaababaabbaabababaaababaabababbaabbabaabababaabbabbbababbababababababaabababaababaaaabababaabab\nabaabababaa\nabaabbaa",
"output": "backward"
},
{
"input": "aaaa\naaa\naa",
"output": "fantasy"
},
{
"input": "zzzz\nzz\nzzz",
"output": "fantasy"
},
{
"input": "zzzz\nzzzz\nzzzz",
"output": "fantasy"
},
{
"input": "zzzz\nzz\nzz",
"output": "both"
},
{
"input": "aabaa\naab\nbaa",
"output": "fantasy"
},
{
"input": "aabaab\naba\nab",
"output": "forward"
},
{
"input": "aab\nb\naa",
"output": "backward"
},
{
"input": "abacaba\naca\nba",
"output": "both"
}
] | 1,593,320,906
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 6
| 186
| 6,656,000
|
flags = input()
p1 = input()
p2 = input()
ab = False
ba = False
if p1 in flags:
if p2 in flags.split(p1, 1)[1]:
ab = True
if p2 in flags:
if p1 in flags.split(p2, 1)[1]:
ba = True
if ab and ba:
print('both')
elif ab and not ba:
print('forward')
elif ab and ba:
print('backward')
else:
print('fantasy')
|
Title: Train and Peter
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
Peter likes to travel by train. He likes it so much that on the train he falls asleep.
Once in summer Peter was going by train from city A to city B, and as usual, was sleeping. Then he woke up, started to look through the window and noticed that every railway station has a flag of a particular colour.
The boy started to memorize the order of the flags' colours that he had seen. But soon he fell asleep again. Unfortunately, he didn't sleep long, he woke up and went on memorizing the colours. Then he fell asleep again, and that time he slept till the end of the journey.
At the station he told his parents about what he was doing, and wrote two sequences of the colours that he had seen before and after his sleep, respectively.
Peter's parents know that their son likes to fantasize. They give you the list of the flags' colours at the stations that the train passes sequentially on the way from A to B, and ask you to find out if Peter could see those sequences on the way from A to B, or from B to A. Remember, please, that Peter had two periods of wakefulness.
Peter's parents put lowercase Latin letters for colours. The same letter stands for the same colour, different letters — for different colours.
Input Specification:
The input data contains three lines. The first line contains a non-empty string, whose length does not exceed 105, the string consists of lowercase Latin letters — the flags' colours at the stations on the way from A to B. On the way from B to A the train passes the same stations, but in reverse order.
The second line contains the sequence, written by Peter during the first period of wakefulness. The third line contains the sequence, written during the second period of wakefulness. Both sequences are non-empty, consist of lowercase Latin letters, and the length of each does not exceed 100 letters. Each of the sequences is written in chronological order.
Output Specification:
Output one of the four words without inverted commas:
- «forward» — if Peter could see such sequences only on the way from A to B; - «backward» — if Peter could see such sequences on the way from B to A; - «both» — if Peter could see such sequences both on the way from A to B, and on the way from B to A; - «fantasy» — if Peter could not see such sequences.
Demo Input:
['atob\na\nb\n', 'aaacaaa\naca\naa\n']
Demo Output:
['forward\n', 'both\n']
Note:
It is assumed that the train moves all the time, so one flag cannot be seen twice. There are no flags at stations A and B.
|
```python
flags = input()
p1 = input()
p2 = input()
ab = False
ba = False
if p1 in flags:
if p2 in flags.split(p1, 1)[1]:
ab = True
if p2 in flags:
if p1 in flags.split(p2, 1)[1]:
ba = True
if ab and ba:
print('both')
elif ab and not ba:
print('forward')
elif ab and ba:
print('backward')
else:
print('fantasy')
```
| 0
|
9
|
C
|
Hexadecimal's Numbers
|
PROGRAMMING
| 1,200
|
[
"brute force",
"implementation",
"math"
] |
C. Hexadecimal's Numbers
|
1
|
64
|
One beautiful July morning a terrible thing happened in Mainframe: a mean virus Megabyte somehow got access to the memory of his not less mean sister Hexadecimal. He loaded there a huge amount of *n* different natural numbers from 1 to *n* to obtain total control over her energy.
But his plan failed. The reason for this was very simple: Hexadecimal didn't perceive any information, apart from numbers written in binary format. This means that if a number in a decimal representation contained characters apart from 0 and 1, it was not stored in the memory. Now Megabyte wants to know, how many numbers were loaded successfully.
|
Input data contains the only number *n* (1<=≤<=*n*<=≤<=109).
|
Output the only number — answer to the problem.
|
[
"10\n"
] |
[
"2"
] |
For *n* = 10 the answer includes numbers 1 and 10.
| 0
|
[
{
"input": "10",
"output": "2"
},
{
"input": "20",
"output": "3"
},
{
"input": "72",
"output": "3"
},
{
"input": "99",
"output": "3"
},
{
"input": "100",
"output": "4"
},
{
"input": "101",
"output": "5"
},
{
"input": "102",
"output": "5"
},
{
"input": "111",
"output": "7"
},
{
"input": "112",
"output": "7"
},
{
"input": "745",
"output": "7"
},
{
"input": "23536",
"output": "31"
},
{
"input": "1",
"output": "1"
},
{
"input": "1010011",
"output": "83"
},
{
"input": "312410141",
"output": "511"
},
{
"input": "1000000000",
"output": "512"
},
{
"input": "999999999",
"output": "511"
},
{
"input": "111111111",
"output": "511"
},
{
"input": "101010101",
"output": "341"
},
{
"input": "121212121",
"output": "511"
},
{
"input": "106341103",
"output": "383"
},
{
"input": "901556123",
"output": "511"
},
{
"input": "832513432",
"output": "511"
},
{
"input": "3",
"output": "1"
},
{
"input": "732875234",
"output": "511"
},
{
"input": "7",
"output": "1"
},
{
"input": "9",
"output": "1"
},
{
"input": "2",
"output": "1"
},
{
"input": "11",
"output": "3"
},
{
"input": "12",
"output": "3"
},
{
"input": "13",
"output": "3"
},
{
"input": "101020101",
"output": "351"
},
{
"input": "111100100",
"output": "484"
},
{
"input": "110110101",
"output": "437"
},
{
"input": "100111001",
"output": "313"
},
{
"input": "100100",
"output": "36"
},
{
"input": "110100102",
"output": "421"
}
] | 1,578,267,987
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 36
| 280
| 0
|
n, b, ans = int(input()), 1, 0
while (n >= b):
ans += 1
b = int(bin(ans + 1)[2:])
print(ans)
|
Title: Hexadecimal's Numbers
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
One beautiful July morning a terrible thing happened in Mainframe: a mean virus Megabyte somehow got access to the memory of his not less mean sister Hexadecimal. He loaded there a huge amount of *n* different natural numbers from 1 to *n* to obtain total control over her energy.
But his plan failed. The reason for this was very simple: Hexadecimal didn't perceive any information, apart from numbers written in binary format. This means that if a number in a decimal representation contained characters apart from 0 and 1, it was not stored in the memory. Now Megabyte wants to know, how many numbers were loaded successfully.
Input Specification:
Input data contains the only number *n* (1<=≤<=*n*<=≤<=109).
Output Specification:
Output the only number — answer to the problem.
Demo Input:
['10\n']
Demo Output:
['2']
Note:
For *n* = 10 the answer includes numbers 1 and 10.
|
```python
n, b, ans = int(input()), 1, 0
while (n >= b):
ans += 1
b = int(bin(ans + 1)[2:])
print(ans)
```
| 3.86
|
455
|
A
|
Boredom
|
PROGRAMMING
| 1,500
|
[
"dp"
] | null | null |
Alex doesn't like boredom. That's why whenever he gets bored, he comes up with games. One long winter evening he came up with a game and decided to play it.
Given a sequence *a* consisting of *n* integers. The player can make several steps. In a single step he can choose an element of the sequence (let's denote it *a**k*) and delete it, at that all elements equal to *a**k*<=+<=1 and *a**k*<=-<=1 also must be deleted from the sequence. That step brings *a**k* points to the player.
Alex is a perfectionist, so he decided to get as many points as possible. Help him.
|
The first line contains integer *n* (1<=≤<=*n*<=≤<=105) that shows how many numbers are in Alex's sequence.
The second line contains *n* integers *a*1, *a*2, ..., *a**n* (1<=≤<=*a**i*<=≤<=105).
|
Print a single integer — the maximum number of points that Alex can earn.
|
[
"2\n1 2\n",
"3\n1 2 3\n",
"9\n1 2 1 3 2 2 2 2 3\n"
] |
[
"2\n",
"4\n",
"10\n"
] |
Consider the third test example. At first step we need to choose any element equal to 2. After that step our sequence looks like this [2, 2, 2, 2]. Then we do 4 steps, on each step we choose any element equals to 2. In total we earn 10 points.
| 500
|
[
{
"input": "2\n1 2",
"output": "2"
},
{
"input": "3\n1 2 3",
"output": "4"
},
{
"input": "9\n1 2 1 3 2 2 2 2 3",
"output": "10"
},
{
"input": "5\n3 3 4 5 4",
"output": "11"
},
{
"input": "5\n5 3 5 3 4",
"output": "16"
},
{
"input": "5\n4 2 3 2 5",
"output": "9"
},
{
"input": "10\n10 5 8 9 5 6 8 7 2 8",
"output": "46"
},
{
"input": "10\n1 1 1 1 1 1 2 3 4 4",
"output": "14"
},
{
"input": "100\n6 6 8 9 7 9 6 9 5 7 7 4 5 3 9 1 10 3 4 5 8 9 6 5 6 4 10 9 1 4 1 7 1 4 9 10 8 2 9 9 10 5 8 9 5 6 8 7 2 8 7 6 2 6 10 8 6 2 5 5 3 2 8 8 5 3 6 2 1 4 7 2 7 3 7 4 10 10 7 5 4 7 5 10 7 1 1 10 7 7 7 2 3 4 2 8 4 7 4 4",
"output": "296"
},
{
"input": "100\n6 1 5 7 10 10 2 7 3 7 2 10 7 6 3 5 5 5 3 7 2 4 2 7 7 4 2 8 2 10 4 7 9 1 1 7 9 7 1 10 10 9 5 6 10 1 7 5 8 1 1 5 3 10 2 4 3 5 2 7 4 9 5 10 1 3 7 6 6 9 3 6 6 10 1 10 6 1 10 3 4 1 7 9 2 7 8 9 3 3 2 4 6 6 1 2 9 4 1 2",
"output": "313"
},
{
"input": "100\n7 6 3 8 8 3 10 5 3 8 6 4 6 9 6 7 3 9 10 7 5 5 9 10 7 2 3 8 9 5 4 7 9 3 6 4 9 10 7 6 8 7 6 6 10 3 7 4 5 7 7 5 1 5 4 8 7 3 3 4 7 8 5 9 2 2 3 1 6 4 6 6 6 1 7 10 7 4 5 3 9 2 4 1 5 10 9 3 9 6 8 5 2 1 10 4 8 5 10 9",
"output": "298"
},
{
"input": "100\n2 10 9 1 2 6 7 2 2 8 9 9 9 5 6 2 5 1 1 10 7 4 5 5 8 1 9 4 10 1 9 3 1 8 4 10 8 8 2 4 6 5 1 4 2 2 1 2 8 5 3 9 4 10 10 7 8 6 1 8 2 6 7 1 6 7 3 10 10 3 7 7 6 9 6 8 8 10 4 6 4 3 3 3 2 3 10 6 8 5 5 10 3 7 3 1 1 1 5 5",
"output": "312"
},
{
"input": "100\n4 9 7 10 4 7 2 6 1 9 1 8 7 5 5 7 6 7 9 8 10 5 3 5 7 10 3 2 1 3 8 9 4 10 4 7 6 4 9 6 7 1 9 4 3 5 8 9 2 7 10 5 7 5 3 8 10 3 8 9 3 4 3 10 6 5 1 8 3 2 5 8 4 7 5 3 3 2 6 9 9 8 2 7 6 3 2 2 8 8 4 5 6 9 2 3 2 2 5 2",
"output": "287"
},
{
"input": "100\n4 8 10 1 8 8 8 1 10 3 1 8 6 8 6 1 10 3 3 3 3 7 2 1 1 6 10 1 7 9 8 10 3 8 6 2 1 6 5 6 10 8 9 7 4 3 10 5 3 9 10 5 10 8 8 5 7 8 9 5 3 9 9 2 7 8 1 10 4 9 2 8 10 10 5 8 5 1 7 3 4 5 2 5 9 3 2 5 6 2 3 10 1 5 9 6 10 4 10 8",
"output": "380"
},
{
"input": "100\n4 8 10 1 8 8 8 1 10 3 1 8 6 8 6 1 10 3 3 3 3 7 2 1 1 6 10 1 7 9 8 10 3 8 6 2 1 6 5 6 10 8 9 7 4 3 10 5 3 9 10 5 10 8 8 5 7 8 9 5 3 9 9 2 7 8 1 10 4 9 2 8 10 10 5 8 5 1 7 3 4 5 2 5 9 3 2 5 6 2 3 10 1 5 9 6 10 4 10 8",
"output": "380"
},
{
"input": "100\n10 5 8 4 4 4 1 4 5 8 3 10 2 4 1 10 8 1 1 6 8 4 2 9 1 3 1 7 7 9 3 5 5 8 6 9 9 4 8 1 3 3 2 6 1 5 4 5 3 5 5 6 7 5 7 9 3 5 4 9 2 6 8 1 1 7 7 3 8 9 8 7 3 2 4 1 6 1 3 9 4 2 2 8 5 10 1 8 8 5 1 5 6 9 4 5 6 5 10 2",
"output": "265"
},
{
"input": "100\n7 5 1 8 5 6 6 2 6 2 7 7 3 6 2 4 4 2 10 2 2 2 10 6 6 1 5 10 9 1 5 9 8 9 4 1 10 5 7 5 7 6 4 8 8 1 7 8 3 8 2 1 8 4 10 3 5 6 6 10 9 6 5 1 10 7 6 9 9 2 10 10 9 1 2 1 7 7 4 10 1 10 5 5 3 8 9 8 1 4 10 2 4 5 4 4 1 6 2 9",
"output": "328"
},
{
"input": "100\n5 6 10 7 1 7 10 1 9 1 5 1 4 1 3 3 7 9 1 6 1 6 5 7 1 6 3 1 3 6 3 8 2 4 1 5 2 10 7 3 10 4 10 1 5 4 2 9 7 9 5 7 10 4 1 4 8 9 3 1 3 7 7 4 3 7 7 10 6 9 5 5 6 5 3 9 8 8 5 5 4 10 9 4 10 4 1 8 3 5 4 10 9 3 10 4 10 7 10 9",
"output": "324"
},
{
"input": "10\n7 4 5 3 9 1 10 3 4 5",
"output": "34"
},
{
"input": "10\n8 9 6 5 6 4 10 9 1 4",
"output": "39"
},
{
"input": "10\n1 7 1 4 9 10 8 2 9 9",
"output": "40"
},
{
"input": "1\n100000",
"output": "100000"
}
] | 1,680,042,995
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 5
| 46
| 0
|
num = int(input())
str1 = input().split()
str1 = [int(r) for r in str1]
lest = []
str1 = tuple(str1)
for x in str1 :
if x not in lest :
lest.append(x)
lest2 = []
str2 = list(str1)
str2.sort()
for x in range(len(lest)):
str2 = list(str1)
if lest[x]+1 in str2 :
for s in str2 :
if lest[x]+1 in str2 :str2.remove((lest[x]+1))
if lest[x]-1 in str2 :
for s in str2 :
if lest[x]-1 in str2 :str2.remove((lest[x]-1))
lest2.append(sum(str2))
print(max(lest2))
|
Title: Boredom
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Alex doesn't like boredom. That's why whenever he gets bored, he comes up with games. One long winter evening he came up with a game and decided to play it.
Given a sequence *a* consisting of *n* integers. The player can make several steps. In a single step he can choose an element of the sequence (let's denote it *a**k*) and delete it, at that all elements equal to *a**k*<=+<=1 and *a**k*<=-<=1 also must be deleted from the sequence. That step brings *a**k* points to the player.
Alex is a perfectionist, so he decided to get as many points as possible. Help him.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=105) that shows how many numbers are in Alex's sequence.
The second line contains *n* integers *a*1, *a*2, ..., *a**n* (1<=≤<=*a**i*<=≤<=105).
Output Specification:
Print a single integer — the maximum number of points that Alex can earn.
Demo Input:
['2\n1 2\n', '3\n1 2 3\n', '9\n1 2 1 3 2 2 2 2 3\n']
Demo Output:
['2\n', '4\n', '10\n']
Note:
Consider the third test example. At first step we need to choose any element equal to 2. After that step our sequence looks like this [2, 2, 2, 2]. Then we do 4 steps, on each step we choose any element equals to 2. In total we earn 10 points.
|
```python
num = int(input())
str1 = input().split()
str1 = [int(r) for r in str1]
lest = []
str1 = tuple(str1)
for x in str1 :
if x not in lest :
lest.append(x)
lest2 = []
str2 = list(str1)
str2.sort()
for x in range(len(lest)):
str2 = list(str1)
if lest[x]+1 in str2 :
for s in str2 :
if lest[x]+1 in str2 :str2.remove((lest[x]+1))
if lest[x]-1 in str2 :
for s in str2 :
if lest[x]-1 in str2 :str2.remove((lest[x]-1))
lest2.append(sum(str2))
print(max(lest2))
```
| 0
|
|
767
|
A
|
Snacktower
|
PROGRAMMING
| 1,100
|
[
"data structures",
"implementation"
] | null | null |
According to an old legeng, a long time ago Ankh-Morpork residents did something wrong to miss Fortune, and she cursed them. She said that at some time *n* snacks of distinct sizes will fall on the city, and the residents should build a Snacktower of them by placing snacks one on another. Of course, big snacks should be at the bottom of the tower, while small snacks should be at the top.
Years passed, and once different snacks started to fall onto the city, and the residents began to build the Snacktower.
However, they faced some troubles. Each day exactly one snack fell onto the city, but their order was strange. So, at some days the residents weren't able to put the new stack on the top of the Snacktower: they had to wait until all the bigger snacks fell. Of course, in order to not to anger miss Fortune again, the residents placed each snack on the top of the tower immediately as they could do it.
Write a program that models the behavior of Ankh-Morpork residents.
|
The first line contains single integer *n* (1<=≤<=*n*<=≤<=100<=000) — the total number of snacks.
The second line contains *n* integers, the *i*-th of them equals the size of the snack which fell on the *i*-th day. Sizes are distinct integers from 1 to *n*.
|
Print *n* lines. On the *i*-th of them print the sizes of the snacks which the residents placed on the top of the Snacktower on the *i*-th day in the order they will do that. If no snack is placed on some day, leave the corresponding line empty.
|
[
"3\n3 1 2\n",
"5\n4 5 1 2 3\n"
] |
[
"3\n \n2 1",
"5 4\n \n \n3 2 1\n"
] |
In the example a snack of size 3 fell on the first day, and the residents immediately placed it. On the second day a snack of size 1 fell, and the residents weren't able to place it because they were missing the snack of size 2. On the third day a snack of size 2 fell, and the residents immediately placed it. Right after that they placed the snack of size 1 which had fallen before.
| 500
|
[
{
"input": "3\n3 1 2",
"output": "3 \n\n2 1 "
},
{
"input": "5\n4 5 1 2 3",
"output": "5 4 \n\n\n3 2 1 "
},
{
"input": "1\n1",
"output": "1 "
},
{
"input": "2\n1 2",
"output": "2 1 "
},
{
"input": "10\n5 1 6 2 8 3 4 10 9 7",
"output": "10 \n9 8 \n7 6 5 4 3 2 1 "
},
{
"input": "30\n16 10 4 29 5 28 12 21 11 30 18 6 14 3 17 22 20 15 9 1 27 19 24 26 13 25 2 23 8 7",
"output": "30 29 28 \n\n\n\n\n\n\n\n\n\n\n27 \n\n\n26 \n\n25 24 \n\n23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 \n8 \n7 6 5 4 3 2 1 "
},
{
"input": "100\n98 52 63 2 18 96 31 58 84 40 41 45 66 100 46 71 26 48 81 20 73 91 68 76 13 93 17 29 64 95 79 21 55 75 19 85 54 51 89 78 15 87 43 59 36 1 90 35 65 56 62 28 86 5 82 49 3 99 33 9 92 32 74 69 27 22 77 16 44 94 34 6 57 70 23 12 61 25 8 11 67 47 83 88 10 14 30 7 97 60 42 37 24 38 53 50 4 80 72 39",
"output": "100 \n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n99 98 \n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 \n\n\n\n\n\n\n\n\n80 79 78 77 76 75 74 73 \n72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 \n39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 "
},
{
"input": "2\n2 1",
"output": "2 \n1 "
}
] | 1,583,520,540
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 25
| 436
| 5,734,400
|
n = int(input())
line = input().split()
nextEl = n
board = []
for i in range(0, n):
board.append(0)
for word in line:
snack = int(word)
board[snack - 1] = 1
if (snack == nextEl):
while (board[nextEl - 1] == 1 and nextEl > 0):
print(nextEl, end=' ')
nextEl = nextEl - 1
print()
|
Title: Snacktower
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
According to an old legeng, a long time ago Ankh-Morpork residents did something wrong to miss Fortune, and she cursed them. She said that at some time *n* snacks of distinct sizes will fall on the city, and the residents should build a Snacktower of them by placing snacks one on another. Of course, big snacks should be at the bottom of the tower, while small snacks should be at the top.
Years passed, and once different snacks started to fall onto the city, and the residents began to build the Snacktower.
However, they faced some troubles. Each day exactly one snack fell onto the city, but their order was strange. So, at some days the residents weren't able to put the new stack on the top of the Snacktower: they had to wait until all the bigger snacks fell. Of course, in order to not to anger miss Fortune again, the residents placed each snack on the top of the tower immediately as they could do it.
Write a program that models the behavior of Ankh-Morpork residents.
Input Specification:
The first line contains single integer *n* (1<=≤<=*n*<=≤<=100<=000) — the total number of snacks.
The second line contains *n* integers, the *i*-th of them equals the size of the snack which fell on the *i*-th day. Sizes are distinct integers from 1 to *n*.
Output Specification:
Print *n* lines. On the *i*-th of them print the sizes of the snacks which the residents placed on the top of the Snacktower on the *i*-th day in the order they will do that. If no snack is placed on some day, leave the corresponding line empty.
Demo Input:
['3\n3 1 2\n', '5\n4 5 1 2 3\n']
Demo Output:
['3\n\xa0\n2 1', '5 4\n\xa0\n\xa0\n3 2 1\n']
Note:
In the example a snack of size 3 fell on the first day, and the residents immediately placed it. On the second day a snack of size 1 fell, and the residents weren't able to place it because they were missing the snack of size 2. On the third day a snack of size 2 fell, and the residents immediately placed it. Right after that they placed the snack of size 1 which had fallen before.
|
```python
n = int(input())
line = input().split()
nextEl = n
board = []
for i in range(0, n):
board.append(0)
for word in line:
snack = int(word)
board[snack - 1] = 1
if (snack == nextEl):
while (board[nextEl - 1] == 1 and nextEl > 0):
print(nextEl, end=' ')
nextEl = nextEl - 1
print()
```
| 3
|
|
870
|
A
|
Search for Pretty Integers
|
PROGRAMMING
| 900
|
[
"brute force",
"implementation"
] | null | null |
You are given two lists of non-zero digits.
Let's call an integer pretty if its (base 10) representation has at least one digit from the first list and at least one digit from the second list. What is the smallest positive pretty integer?
|
The first line contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=9) — the lengths of the first and the second lists, respectively.
The second line contains *n* distinct digits *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=9) — the elements of the first list.
The third line contains *m* distinct digits *b*1,<=*b*2,<=...,<=*b**m* (1<=≤<=*b**i*<=≤<=9) — the elements of the second list.
|
Print the smallest pretty integer.
|
[
"2 3\n4 2\n5 7 6\n",
"8 8\n1 2 3 4 5 6 7 8\n8 7 6 5 4 3 2 1\n"
] |
[
"25\n",
"1\n"
] |
In the first example 25, 46, 24567 are pretty, as well as many other integers. The smallest among them is 25. 42 and 24 are not pretty because they don't have digits from the second list.
In the second example all integers that have at least one digit different from 9 are pretty. It's obvious that the smallest among them is 1, because it's the smallest positive integer.
| 500
|
[
{
"input": "2 3\n4 2\n5 7 6",
"output": "25"
},
{
"input": "8 8\n1 2 3 4 5 6 7 8\n8 7 6 5 4 3 2 1",
"output": "1"
},
{
"input": "1 1\n9\n1",
"output": "19"
},
{
"input": "9 1\n5 4 2 3 6 1 7 9 8\n9",
"output": "9"
},
{
"input": "5 3\n7 2 5 8 6\n3 1 9",
"output": "12"
},
{
"input": "4 5\n5 2 6 4\n8 9 1 3 7",
"output": "12"
},
{
"input": "5 9\n4 2 1 6 7\n2 3 4 5 6 7 8 9 1",
"output": "1"
},
{
"input": "9 9\n5 4 3 2 1 6 7 8 9\n3 2 1 5 4 7 8 9 6",
"output": "1"
},
{
"input": "9 5\n2 3 4 5 6 7 8 9 1\n4 2 1 6 7",
"output": "1"
},
{
"input": "9 9\n1 2 3 4 5 6 7 8 9\n1 2 3 4 5 6 7 8 9",
"output": "1"
},
{
"input": "9 9\n1 2 3 4 5 6 7 8 9\n9 8 7 6 5 4 3 2 1",
"output": "1"
},
{
"input": "9 9\n9 8 7 6 5 4 3 2 1\n1 2 3 4 5 6 7 8 9",
"output": "1"
},
{
"input": "9 9\n9 8 7 6 5 4 3 2 1\n9 8 7 6 5 4 3 2 1",
"output": "1"
},
{
"input": "1 1\n8\n9",
"output": "89"
},
{
"input": "1 1\n9\n8",
"output": "89"
},
{
"input": "1 1\n1\n2",
"output": "12"
},
{
"input": "1 1\n2\n1",
"output": "12"
},
{
"input": "1 1\n9\n9",
"output": "9"
},
{
"input": "1 1\n1\n1",
"output": "1"
},
{
"input": "4 5\n3 2 4 5\n1 6 5 9 8",
"output": "5"
},
{
"input": "3 2\n4 5 6\n1 5",
"output": "5"
},
{
"input": "5 4\n1 3 5 6 7\n2 4 3 9",
"output": "3"
},
{
"input": "5 5\n1 3 5 7 9\n2 4 6 8 9",
"output": "9"
},
{
"input": "2 2\n1 8\n2 8",
"output": "8"
},
{
"input": "5 5\n5 6 7 8 9\n1 2 3 4 5",
"output": "5"
},
{
"input": "5 5\n1 2 3 4 5\n1 2 3 4 5",
"output": "1"
},
{
"input": "5 5\n1 2 3 4 5\n2 3 4 5 6",
"output": "2"
},
{
"input": "2 2\n1 5\n2 5",
"output": "5"
},
{
"input": "4 4\n1 3 5 8\n2 4 6 8",
"output": "8"
},
{
"input": "3 3\n1 5 3\n2 5 7",
"output": "5"
},
{
"input": "3 3\n3 6 8\n2 6 9",
"output": "6"
},
{
"input": "2 2\n1 4\n2 4",
"output": "4"
},
{
"input": "5 3\n3 4 5 6 7\n1 5 9",
"output": "5"
},
{
"input": "4 4\n1 2 3 4\n2 5 6 7",
"output": "2"
},
{
"input": "5 5\n1 2 3 4 5\n9 2 1 7 5",
"output": "1"
},
{
"input": "2 2\n1 3\n2 3",
"output": "3"
},
{
"input": "3 3\n3 2 1\n3 2 1",
"output": "1"
},
{
"input": "3 3\n1 3 5\n2 3 6",
"output": "3"
},
{
"input": "3 3\n5 6 7\n5 6 7",
"output": "5"
},
{
"input": "1 2\n5\n2 5",
"output": "5"
},
{
"input": "3 3\n2 4 9\n7 8 9",
"output": "9"
},
{
"input": "3 3\n1 2 4\n3 4 5",
"output": "4"
},
{
"input": "3 2\n1 4 9\n2 4",
"output": "4"
},
{
"input": "3 3\n3 5 6\n1 5 9",
"output": "5"
},
{
"input": "3 2\n1 2 4\n3 4",
"output": "4"
},
{
"input": "2 4\n8 9\n1 2 3 9",
"output": "9"
},
{
"input": "1 2\n9\n8 9",
"output": "9"
},
{
"input": "3 2\n1 2 4\n4 2",
"output": "2"
},
{
"input": "2 3\n4 5\n1 3 5",
"output": "5"
},
{
"input": "3 2\n1 2 3\n2 3",
"output": "2"
},
{
"input": "4 3\n1 3 5 9\n2 8 9",
"output": "9"
},
{
"input": "2 2\n1 9\n9 2",
"output": "9"
}
] | 1,586,500,752
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 3
| 124
| 0
|
n,m=map(int,input().split())
l=list(map(int,input().split()))
d=list(map(int,input().split()))
a=min(l)
b=min(d)
if(a<b):
x=str(a)+str(b)
elif(a>b):
x=str(b)+str(a)
else:
x=a
print(x)
|
Title: Search for Pretty Integers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given two lists of non-zero digits.
Let's call an integer pretty if its (base 10) representation has at least one digit from the first list and at least one digit from the second list. What is the smallest positive pretty integer?
Input Specification:
The first line contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=9) — the lengths of the first and the second lists, respectively.
The second line contains *n* distinct digits *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=9) — the elements of the first list.
The third line contains *m* distinct digits *b*1,<=*b*2,<=...,<=*b**m* (1<=≤<=*b**i*<=≤<=9) — the elements of the second list.
Output Specification:
Print the smallest pretty integer.
Demo Input:
['2 3\n4 2\n5 7 6\n', '8 8\n1 2 3 4 5 6 7 8\n8 7 6 5 4 3 2 1\n']
Demo Output:
['25\n', '1\n']
Note:
In the first example 25, 46, 24567 are pretty, as well as many other integers. The smallest among them is 25. 42 and 24 are not pretty because they don't have digits from the second list.
In the second example all integers that have at least one digit different from 9 are pretty. It's obvious that the smallest among them is 1, because it's the smallest positive integer.
|
```python
n,m=map(int,input().split())
l=list(map(int,input().split()))
d=list(map(int,input().split()))
a=min(l)
b=min(d)
if(a<b):
x=str(a)+str(b)
elif(a>b):
x=str(b)+str(a)
else:
x=a
print(x)
```
| 0
|
|
688
|
A
|
Opponents
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Arya has *n* opponents in the school. Each day he will fight with all opponents who are present this day. His opponents have some fighting plan that guarantees they will win, but implementing this plan requires presence of them all. That means if one day at least one of Arya's opponents is absent at the school, then Arya will beat all present opponents. Otherwise, if all opponents are present, then they will beat Arya.
For each opponent Arya knows his schedule — whether or not he is going to present on each particular day. Tell him the maximum number of consecutive days that he will beat all present opponents.
Note, that if some day there are no opponents present, Arya still considers he beats all the present opponents.
|
The first line of the input contains two integers *n* and *d* (1<=≤<=*n*,<=*d*<=≤<=100) — the number of opponents and the number of days, respectively.
The *i*-th of the following *d* lines contains a string of length *n* consisting of characters '0' and '1'. The *j*-th character of this string is '0' if the *j*-th opponent is going to be absent on the *i*-th day.
|
Print the only integer — the maximum number of consecutive days that Arya will beat all present opponents.
|
[
"2 2\n10\n00\n",
"4 1\n0100\n",
"4 5\n1101\n1111\n0110\n1011\n1111\n"
] |
[
"2\n",
"1\n",
"2\n"
] |
In the first and the second samples, Arya will beat all present opponents each of the *d* days.
In the third sample, Arya will beat his opponents on days 1, 3 and 4 and his opponents will beat him on days 2 and 5. Thus, the maximum number of consecutive winning days is 2, which happens on days 3 and 4.
| 500
|
[
{
"input": "2 2\n10\n00",
"output": "2"
},
{
"input": "4 1\n0100",
"output": "1"
},
{
"input": "4 5\n1101\n1111\n0110\n1011\n1111",
"output": "2"
},
{
"input": "3 2\n110\n110",
"output": "2"
},
{
"input": "10 6\n1111111111\n0100110101\n1111111111\n0000011010\n1111111111\n1111111111",
"output": "1"
},
{
"input": "10 10\n1111111111\n0001001000\n1111111111\n1111111111\n1111111111\n1000000100\n1111111111\n0000011100\n1111111111\n1111111111",
"output": "1"
},
{
"input": "10 10\n0000100011\n0100001111\n1111111111\n1100011111\n1111111111\n1000111000\n1111000010\n0111001001\n1101010110\n1111111111",
"output": "4"
},
{
"input": "10 10\n1100110010\n0000000001\n1011100111\n1111111111\n1111111111\n1111111111\n1100010110\n1111111111\n1001001010\n1111111111",
"output": "3"
},
{
"input": "10 7\n0000111001\n1111111111\n0110110001\n1111111111\n1111111111\n1000111100\n0110000111",
"output": "2"
},
{
"input": "5 10\n00110\n11000\n10010\n00010\n11110\n01101\n11111\n10001\n11111\n01001",
"output": "6"
},
{
"input": "5 9\n11111\n11101\n11111\n11111\n01010\n01010\n00000\n11111\n00111",
"output": "3"
},
{
"input": "5 10\n11111\n00010\n11010\n11111\n11111\n00100\n11111\n11111\n01000\n11111",
"output": "2"
},
{
"input": "5 9\n11111\n11111\n11111\n11111\n11100\n11111\n11111\n11111\n00000",
"output": "1"
},
{
"input": "5 8\n11111\n10110\n01001\n11111\n01100\n10010\n11111\n11111",
"output": "2"
},
{
"input": "1 1\n1",
"output": "0"
},
{
"input": "100 1\n0011001100100010000011001100000001011101110110010001110001101100110011111101001011011001000010001111",
"output": "1"
},
{
"input": "100 1\n1011011100000101000111110000110111010101110010010011110010001110100011001110110101111100100110000000",
"output": "1"
},
{
"input": "100 1\n1110000011110101010111111100011001100000101101010110100101110000011100110110110101011100110110010011",
"output": "1"
},
{
"input": "100 1\n1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111",
"output": "0"
},
{
"input": "1 100\n1\n0\n0\n0\n1\n1\n0\n0\n0\n0\n1\n1\n0\n1\n1\n0\n0\n1\n1\n1\n0\n0\n1\n1\n1\n1\n1\n0\n1\n0\n0\n0\n1\n1\n0\n1\n0\n1\n0\n0\n0\n1\n0\n1\n0\n0\n0\n1\n1\n1\n0\n1\n1\n1\n0\n1\n0\n1\n1\n1\n1\n0\n0\n0\n0\n0\n0\n1\n1\n0\n1\n1\n1\n1\n1\n0\n1\n1\n1\n1\n1\n0\n1\n0\n0\n1\n0\n0\n1\n0\n0\n1\n0\n1\n1\n1\n0\n1\n0\n0",
"output": "6"
},
{
"input": "1 100\n0\n0\n0\n0\n1\n0\n0\n0\n0\n1\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n1\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0",
"output": "49"
},
{
"input": "1 100\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1",
"output": "0"
},
{
"input": "1 100\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0",
"output": "100"
},
{
"input": "2 2\n11\n10",
"output": "1"
},
{
"input": "1 1\n0",
"output": "1"
}
] | 1,586,870,901
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 56
| 124
| 0
|
n, d = input().split()
n, d = int(n), int(d)
presence = []
for i in range(0,d):
presence.append(input())
k = 0
maximo = 0
for i in range(0,d):
if '0' in presence[i]:
k += 1
else:
k = 0
if k > maximo:
maximo = k
print(maximo)
|
Title: Opponents
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Arya has *n* opponents in the school. Each day he will fight with all opponents who are present this day. His opponents have some fighting plan that guarantees they will win, but implementing this plan requires presence of them all. That means if one day at least one of Arya's opponents is absent at the school, then Arya will beat all present opponents. Otherwise, if all opponents are present, then they will beat Arya.
For each opponent Arya knows his schedule — whether or not he is going to present on each particular day. Tell him the maximum number of consecutive days that he will beat all present opponents.
Note, that if some day there are no opponents present, Arya still considers he beats all the present opponents.
Input Specification:
The first line of the input contains two integers *n* and *d* (1<=≤<=*n*,<=*d*<=≤<=100) — the number of opponents and the number of days, respectively.
The *i*-th of the following *d* lines contains a string of length *n* consisting of characters '0' and '1'. The *j*-th character of this string is '0' if the *j*-th opponent is going to be absent on the *i*-th day.
Output Specification:
Print the only integer — the maximum number of consecutive days that Arya will beat all present opponents.
Demo Input:
['2 2\n10\n00\n', '4 1\n0100\n', '4 5\n1101\n1111\n0110\n1011\n1111\n']
Demo Output:
['2\n', '1\n', '2\n']
Note:
In the first and the second samples, Arya will beat all present opponents each of the *d* days.
In the third sample, Arya will beat his opponents on days 1, 3 and 4 and his opponents will beat him on days 2 and 5. Thus, the maximum number of consecutive winning days is 2, which happens on days 3 and 4.
|
```python
n, d = input().split()
n, d = int(n), int(d)
presence = []
for i in range(0,d):
presence.append(input())
k = 0
maximo = 0
for i in range(0,d):
if '0' in presence[i]:
k += 1
else:
k = 0
if k > maximo:
maximo = k
print(maximo)
```
| 3
|
|
58
|
A
|
Chat room
|
PROGRAMMING
| 1,000
|
[
"greedy",
"strings"
] |
A. Chat room
|
1
|
256
|
Vasya has recently learned to type and log on to the Internet. He immediately entered a chat room and decided to say hello to everybody. Vasya typed the word *s*. It is considered that Vasya managed to say hello if several letters can be deleted from the typed word so that it resulted in the word "hello". For example, if Vasya types the word "ahhellllloou", it will be considered that he said hello, and if he types "hlelo", it will be considered that Vasya got misunderstood and he didn't manage to say hello. Determine whether Vasya managed to say hello by the given word *s*.
|
The first and only line contains the word *s*, which Vasya typed. This word consisits of small Latin letters, its length is no less that 1 and no more than 100 letters.
|
If Vasya managed to say hello, print "YES", otherwise print "NO".
|
[
"ahhellllloou\n",
"hlelo\n"
] |
[
"YES\n",
"NO\n"
] |
none
| 500
|
[
{
"input": "ahhellllloou",
"output": "YES"
},
{
"input": "hlelo",
"output": "NO"
},
{
"input": "helhcludoo",
"output": "YES"
},
{
"input": "hehwelloho",
"output": "YES"
},
{
"input": "pnnepelqomhhheollvlo",
"output": "YES"
},
{
"input": "tymbzjyqhymedasloqbq",
"output": "NO"
},
{
"input": "yehluhlkwo",
"output": "NO"
},
{
"input": "hatlevhhalrohairnolsvocafgueelrqmlqlleello",
"output": "YES"
},
{
"input": "hhhtehdbllnhwmbyhvelqqyoulretpbfokflhlhreeflxeftelziclrwllrpflflbdtotvlqgoaoqldlroovbfsq",
"output": "YES"
},
{
"input": "rzlvihhghnelqtwlexmvdjjrliqllolhyewgozkuovaiezgcilelqapuoeglnwmnlftxxiigzczlouooi",
"output": "YES"
},
{
"input": "pfhhwctyqdlkrwhebfqfelhyebwllhemtrmeblgrynmvyhioesqklclocxmlffuormljszllpoo",
"output": "YES"
},
{
"input": "lqllcolohwflhfhlnaow",
"output": "NO"
},
{
"input": "heheeellollvoo",
"output": "YES"
},
{
"input": "hellooo",
"output": "YES"
},
{
"input": "o",
"output": "NO"
},
{
"input": "hhqhzeclohlehljlhtesllylrolmomvuhcxsobtsckogdv",
"output": "YES"
},
{
"input": "yoegfuzhqsihygnhpnukluutocvvwuldiighpogsifealtgkfzqbwtmgghmythcxflebrkctlldlkzlagovwlstsghbouk",
"output": "YES"
},
{
"input": "uatqtgbvrnywfacwursctpagasnhydvmlinrcnqrry",
"output": "NO"
},
{
"input": "tndtbldbllnrwmbyhvqaqqyoudrstpbfokfoclnraefuxtftmgzicorwisrpfnfpbdtatvwqgyalqtdtrjqvbfsq",
"output": "NO"
},
{
"input": "rzlvirhgemelnzdawzpaoqtxmqucnahvqnwldklrmjiiyageraijfivigvozgwngiulttxxgzczptusoi",
"output": "YES"
},
{
"input": "kgyelmchocojsnaqdsyeqgnllytbqietpdlgknwwumqkxrexgdcnwoldicwzwofpmuesjuxzrasscvyuqwspm",
"output": "YES"
},
{
"input": "pnyvrcotjvgynbeldnxieghfltmexttuxzyac",
"output": "NO"
},
{
"input": "dtwhbqoumejligbenxvzhjlhosqojetcqsynlzyhfaevbdpekgbtjrbhlltbceobcok",
"output": "YES"
},
{
"input": "crrfpfftjwhhikwzeedrlwzblckkteseofjuxjrktcjfsylmlsvogvrcxbxtffujqshslemnixoeezivksouefeqlhhokwbqjz",
"output": "YES"
},
{
"input": "jhfbndhyzdvhbvhmhmefqllujdflwdpjbehedlsqfdsqlyelwjtyloxwsvasrbqosblzbowlqjmyeilcvotdlaouxhdpoeloaovb",
"output": "YES"
},
{
"input": "hwlghueoemiqtjhhpashjsouyegdlvoyzeunlroypoprnhlyiwiuxrghekaylndhrhllllwhbebezoglydcvykllotrlaqtvmlla",
"output": "YES"
},
{
"input": "wshiaunnqnqxodholbipwhhjmyeblhgpeleblklpzwhdunmpqkbuzloetmwwxmeltkrcomulxauzlwmlklldjodozxryghsnwgcz",
"output": "YES"
},
{
"input": "shvksednttggehroewuiptvvxtrzgidravtnjwuqrlnnkxbplctzkckinpkgjopjfoxdbojtcvsuvablcbkrzajrlhgobkcxeqti",
"output": "YES"
},
{
"input": "hyyhddqhxhekehkwfhlnlsihzefwchzerevcjtokefplholrbvxlltdlafjxrfhleglrvlolojoqaolagtbeyogxlbgfolllslli",
"output": "YES"
},
{
"input": "iaagrdhhelxpdegueiulflquvlzidoprzkehthkldaytrjwhyhprwjxlltinxvuilxohqgjqcvkkdcuoliekcnlilwgqlnlzouoo",
"output": "YES"
},
{
"input": "wfluaeseldgxyvxpwuhkptdmlflnlhktwxiabsvkolsquymrmhzczzoybvlilhmvsuunggvgxzgyyffk",
"output": "NO"
},
{
"input": "loee",
"output": "NO"
},
{
"input": "izdipwylefqmjbuoznfglgcfvedeouflkeehxbasaqmiooppfsqlhprospqgxvzrcpwlfdddngoqvpwvggsnvvxhmjoslwjudjlo",
"output": "NO"
},
{
"input": "pplynflbjlseflaegzqpdxswgunhnlglqhycrbcwdfhclmcrwekkzsoosmfblljeenwfjyifcvxihhhbyhmhlkvtskeglaovjnsi",
"output": "YES"
},
{
"input": "xqjqmenkodmlhzyzmmvofdngktygbbxbzpluzcohohmalkoeuwfikblltaaigv",
"output": "NO"
},
{
"input": "hello",
"output": "YES"
},
{
"input": "oohell",
"output": "NO"
},
{
"input": "hell",
"output": "NO"
},
{
"input": "eloellohoelo",
"output": "NO"
},
{
"input": "helllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllo",
"output": "YES"
}
] | 1,660,579,930
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 40
| 46
| 0
|
t='hello'
s=input()
i=0
n=5
for j in s:
if j==t[i]:
i+=1
if i==n:
break
if i==n:
print("YES")
else:
print("NO")
|
Title: Chat room
Time Limit: 1 seconds
Memory Limit: 256 megabytes
Problem Description:
Vasya has recently learned to type and log on to the Internet. He immediately entered a chat room and decided to say hello to everybody. Vasya typed the word *s*. It is considered that Vasya managed to say hello if several letters can be deleted from the typed word so that it resulted in the word "hello". For example, if Vasya types the word "ahhellllloou", it will be considered that he said hello, and if he types "hlelo", it will be considered that Vasya got misunderstood and he didn't manage to say hello. Determine whether Vasya managed to say hello by the given word *s*.
Input Specification:
The first and only line contains the word *s*, which Vasya typed. This word consisits of small Latin letters, its length is no less that 1 and no more than 100 letters.
Output Specification:
If Vasya managed to say hello, print "YES", otherwise print "NO".
Demo Input:
['ahhellllloou\n', 'hlelo\n']
Demo Output:
['YES\n', 'NO\n']
Note:
none
|
```python
t='hello'
s=input()
i=0
n=5
for j in s:
if j==t[i]:
i+=1
if i==n:
break
if i==n:
print("YES")
else:
print("NO")
```
| 3.977
|
262
|
A
|
Roma and Lucky Numbers
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Roma (a popular Russian name that means 'Roman') loves the Little Lvov Elephant's lucky numbers.
Let us remind you that lucky numbers are positive integers whose decimal representation only contains lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Roma's got *n* positive integers. He wonders, how many of those integers have not more than *k* lucky digits? Help him, write the program that solves the problem.
|
The first line contains two integers *n*, *k* (1<=≤<=*n*,<=*k*<=≤<=100). The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=109) — the numbers that Roma has.
The numbers in the lines are separated by single spaces.
|
In a single line print a single integer — the answer to the problem.
|
[
"3 4\n1 2 4\n",
"3 2\n447 44 77\n"
] |
[
"3\n",
"2\n"
] |
In the first sample all numbers contain at most four lucky digits, so the answer is 3.
In the second sample number 447 doesn't fit in, as it contains more than two lucky digits. All other numbers are fine, so the answer is 2.
| 500
|
[
{
"input": "3 4\n1 2 4",
"output": "3"
},
{
"input": "3 2\n447 44 77",
"output": "2"
},
{
"input": "2 2\n507978501 180480073",
"output": "2"
},
{
"input": "9 6\n655243746 167613748 1470546 57644035 176077477 56984809 44677 215706823 369042089",
"output": "9"
},
{
"input": "6 100\n170427799 37215529 675016434 168544291 683447134 950090227",
"output": "6"
},
{
"input": "4 2\n194041605 706221269 69909135 257655784",
"output": "3"
},
{
"input": "4 2\n9581849 67346651 530497 272158241",
"output": "4"
},
{
"input": "3 47\n378261451 163985731 230342101",
"output": "3"
},
{
"input": "2 3\n247776868 480572137",
"output": "1"
},
{
"input": "7 77\n366496749 549646417 278840199 119255907 33557677 379268590 150378796",
"output": "7"
},
{
"input": "40 31\n32230963 709031779 144328646 513494529 36547831 416998222 84161665 318773941 170724397 553666286 368402971 48581613 31452501 368026285 47903381 939151438 204145360 189920160 288159400 133145006 314295423 450219949 160203213 358403181 478734385 29331901 31051111 110710191 567314089 139695685 111511396 87708701 317333277 103301481 110400517 634446253 481551313 39202255 105948 738066085",
"output": "40"
},
{
"input": "1 8\n55521105",
"output": "1"
},
{
"input": "49 3\n34644511 150953622 136135827 144208961 359490601 86708232 719413689 188605873 64330753 488776302 104482891 63360106 437791390 46521319 70778345 339141601 136198441 292941209 299339510 582531183 555958105 437904637 74219097 439816011 236010407 122674666 438442529 186501223 63932449 407678041 596993853 92223251 849265278 480265849 30983497 330283357 186901672 20271344 794252593 123774176 27851201 52717531 479907210 196833889 149331196 82147847 255966471 278600081 899317843",
"output": "44"
},
{
"input": "26 2\n330381357 185218042 850474297 483015466 296129476 1205865 538807493 103205601 160403321 694220263 416255901 7245756 507755361 88187633 91426751 1917161 58276681 59540376 576539745 595950717 390256887 105690055 607818885 28976353 488947089 50643601",
"output": "22"
},
{
"input": "38 1\n194481717 126247087 815196361 106258801 381703249 283859137 15290101 40086151 213688513 577996947 513899717 371428417 107799271 11136651 5615081 323386401 381128815 34217126 17709913 520702093 201694245 570931849 169037023 417019726 282437316 7417126 271667553 11375851 185087449 410130883 383045677 5764771 905017051 328584026 215330671 299553233 15838255 234532105",
"output": "20"
},
{
"input": "44 9\n683216389 250581469 130029957 467020047 188395565 206237982 63257361 68314981 732878407 563579660 199133851 53045209 665723851 16273169 10806790 556633156 350593410 474645249 478790761 708234243 71841230 18090541 19836685 146373571 17947452 534010506 46933264 377035021 311636557 75193963 54321761 12759959 71120181 548816939 23608621 31876417 107672995 72575155 369667956 20574379 210596751 532163173 75726739 853719629",
"output": "44"
},
{
"input": "8 6\n204157376 10514197 65483881 347219841 263304577 296402721 11739011 229776191",
"output": "8"
},
{
"input": "38 29\n333702889 680931737 61137217 203030505 68728281 11414209 642645708 590904616 3042901 607198177 189041074 700764043 813035201 198341461 126403544 401436841 420826465 45046581 20249976 46978855 46397957 706610773 24701041 57954481 51603266 593109701 385569073 178982291 582152863 287317968 1474090 34825141 432421977 130257781 151516903 540852403 548392 117246529",
"output": "38"
},
{
"input": "19 3\n562569697 549131571 50676718 84501863 74567295 702372009 365895280 451459937 40378543 167666701 158635641 53639293 442332661 825055617 100109161 326616021 862332843 533271196 4791547",
"output": "18"
},
{
"input": "1 1\n44",
"output": "0"
},
{
"input": "1 1\n4",
"output": "1"
},
{
"input": "10 3\n444 447 774 777 7777 4447 4 7 7 4",
"output": "8"
}
] | 1,592,150,932
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 34
| 248
| 0
|
def countLucky(number):
count = 0; temp = 0
while number > 0:
temp = number % 10
if temp == 4 or temp == 7:
count += 1
number = int(number/10)
return count
count = 0
n, k = map(int,input().split())
lst = list(map(int,input().split()))
for i in range(n):
if countLucky(lst[i]) <= k :
count += 1
print(count)
|
Title: Roma and Lucky Numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Roma (a popular Russian name that means 'Roman') loves the Little Lvov Elephant's lucky numbers.
Let us remind you that lucky numbers are positive integers whose decimal representation only contains lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Roma's got *n* positive integers. He wonders, how many of those integers have not more than *k* lucky digits? Help him, write the program that solves the problem.
Input Specification:
The first line contains two integers *n*, *k* (1<=≤<=*n*,<=*k*<=≤<=100). The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=109) — the numbers that Roma has.
The numbers in the lines are separated by single spaces.
Output Specification:
In a single line print a single integer — the answer to the problem.
Demo Input:
['3 4\n1 2 4\n', '3 2\n447 44 77\n']
Demo Output:
['3\n', '2\n']
Note:
In the first sample all numbers contain at most four lucky digits, so the answer is 3.
In the second sample number 447 doesn't fit in, as it contains more than two lucky digits. All other numbers are fine, so the answer is 2.
|
```python
def countLucky(number):
count = 0; temp = 0
while number > 0:
temp = number % 10
if temp == 4 or temp == 7:
count += 1
number = int(number/10)
return count
count = 0
n, k = map(int,input().split())
lst = list(map(int,input().split()))
for i in range(n):
if countLucky(lst[i]) <= k :
count += 1
print(count)
```
| 3
|
|
137
|
B
|
Permutation
|
PROGRAMMING
| 1,000
|
[
"greedy"
] | null | null |
"Hey, it's homework time" — thought Polycarpus and of course he started with his favourite subject, IT. Polycarpus managed to solve all tasks but for the last one in 20 minutes. However, as he failed to solve the last task after some considerable time, the boy asked you to help him.
The sequence of *n* integers is called a permutation if it contains all integers from 1 to *n* exactly once.
You are given an arbitrary sequence *a*1,<=*a*2,<=...,<=*a**n* containing *n* integers. Each integer is not less than 1 and not greater than 5000. Determine what minimum number of elements Polycarpus needs to change to get a permutation (he should not delete or add numbers). In a single change he can modify any single sequence element (i. e. replace it with another integer).
|
The first line of the input data contains an integer *n* (1<=≤<=*n*<=≤<=5000) which represents how many numbers are in the sequence. The second line contains a sequence of integers *a**i* (1<=≤<=*a**i*<=≤<=5000,<=1<=≤<=*i*<=≤<=*n*).
|
Print the only number — the minimum number of changes needed to get the permutation.
|
[
"3\n3 1 2\n",
"2\n2 2\n",
"5\n5 3 3 3 1\n"
] |
[
"0\n",
"1\n",
"2\n"
] |
The first sample contains the permutation, which is why no replacements are required.
In the second sample it is enough to replace the first element with the number 1 and that will make the sequence the needed permutation.
In the third sample we can replace the second element with number 4 and the fourth element with number 2.
| 1,000
|
[
{
"input": "3\n3 1 2",
"output": "0"
},
{
"input": "2\n2 2",
"output": "1"
},
{
"input": "5\n5 3 3 3 1",
"output": "2"
},
{
"input": "5\n6 6 6 6 6",
"output": "5"
},
{
"input": "10\n1 1 2 2 8 8 7 7 9 9",
"output": "5"
},
{
"input": "8\n9 8 7 6 5 4 3 2",
"output": "1"
},
{
"input": "15\n1 2 3 4 5 5 4 3 2 1 1 2 3 4 5",
"output": "10"
},
{
"input": "1\n1",
"output": "0"
},
{
"input": "1\n5000",
"output": "1"
},
{
"input": "4\n5000 5000 5000 5000",
"output": "4"
},
{
"input": "5\n3366 3461 4 5 4370",
"output": "3"
},
{
"input": "10\n8 2 10 3 4 6 1 7 9 5",
"output": "0"
},
{
"input": "10\n551 3192 3213 2846 3068 1224 3447 1 10 9",
"output": "7"
},
{
"input": "15\n4 1459 12 4281 3241 2748 10 3590 14 845 3518 1721 2 2880 1974",
"output": "10"
},
{
"input": "15\n15 1 8 2 13 11 12 7 3 14 6 10 9 4 5",
"output": "0"
},
{
"input": "15\n2436 2354 4259 1210 2037 2665 700 3578 2880 973 1317 1024 24 3621 4142",
"output": "15"
},
{
"input": "30\n28 1 3449 9 3242 4735 26 3472 15 21 2698 7 4073 3190 10 3 29 1301 4526 22 345 3876 19 12 4562 2535 2 630 18 27",
"output": "14"
},
{
"input": "100\n50 39 95 30 66 78 2169 4326 81 31 74 34 80 40 19 48 97 63 82 6 88 16 21 57 92 77 10 1213 17 93 32 91 38 4375 29 75 44 22 4 45 14 2395 3254 59 3379 2 85 96 8 83 27 94 1512 2960 100 9 73 79 7 25 55 69 90 99 51 87 98 62 18 35 43 4376 4668 28 72 56 4070 61 65 36 54 4106 11 24 15 86 70 71 4087 23 13 76 20 4694 26 4962 4726 37 14 64",
"output": "18"
},
{
"input": "100\n340 14 3275 2283 2673 1107 817 2243 1226 32 2382 3638 4652 418 68 4962 387 764 4647 159 1846 225 2760 4904 3150 403 3 2439 91 4428 92 4705 75 348 1566 1465 69 6 49 4 62 4643 564 1090 3447 1871 2255 139 24 99 2669 969 86 61 4550 158 4537 3993 1589 872 2907 1888 401 80 1825 1483 63 1 2264 4068 4113 2548 41 885 4806 36 67 167 4447 34 1248 2593 82 202 81 1783 1284 4973 16 43 95 7 865 2091 3008 1793 20 947 4912 3604",
"output": "70"
},
{
"input": "1\n2",
"output": "1"
},
{
"input": "2\n5000 5000",
"output": "2"
},
{
"input": "2\n1 2",
"output": "0"
},
{
"input": "2\n1 1",
"output": "1"
},
{
"input": "2\n2 3",
"output": "1"
},
{
"input": "2\n3 4",
"output": "2"
},
{
"input": "10\n1 2 3 4 5 6 7 1000 10 10",
"output": "2"
}
] | 1,632,773,296
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 3
| 124
| 6,758,400
|
n = int(input())
nums = set(map(int, input().split()))
print(n - len(nums))
|
Title: Permutation
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
"Hey, it's homework time" — thought Polycarpus and of course he started with his favourite subject, IT. Polycarpus managed to solve all tasks but for the last one in 20 minutes. However, as he failed to solve the last task after some considerable time, the boy asked you to help him.
The sequence of *n* integers is called a permutation if it contains all integers from 1 to *n* exactly once.
You are given an arbitrary sequence *a*1,<=*a*2,<=...,<=*a**n* containing *n* integers. Each integer is not less than 1 and not greater than 5000. Determine what minimum number of elements Polycarpus needs to change to get a permutation (he should not delete or add numbers). In a single change he can modify any single sequence element (i. e. replace it with another integer).
Input Specification:
The first line of the input data contains an integer *n* (1<=≤<=*n*<=≤<=5000) which represents how many numbers are in the sequence. The second line contains a sequence of integers *a**i* (1<=≤<=*a**i*<=≤<=5000,<=1<=≤<=*i*<=≤<=*n*).
Output Specification:
Print the only number — the minimum number of changes needed to get the permutation.
Demo Input:
['3\n3 1 2\n', '2\n2 2\n', '5\n5 3 3 3 1\n']
Demo Output:
['0\n', '1\n', '2\n']
Note:
The first sample contains the permutation, which is why no replacements are required.
In the second sample it is enough to replace the first element with the number 1 and that will make the sequence the needed permutation.
In the third sample we can replace the second element with number 4 and the fourth element with number 2.
|
```python
n = int(input())
nums = set(map(int, input().split()))
print(n - len(nums))
```
| 0
|
|
63
|
A
|
Sinking Ship
|
PROGRAMMING
| 900
|
[
"implementation",
"sortings",
"strings"
] |
A. Sinking Ship
|
2
|
256
|
The ship crashed into a reef and is sinking. Now the entire crew must be evacuated. All *n* crew members have already lined up in a row (for convenience let's label them all from left to right with positive integers from 1 to *n*) and await further instructions. However, one should evacuate the crew properly, in a strict order. Specifically:
The first crew members to leave the ship are rats. Then women and children (both groups have the same priority) leave the ship. After that all men are evacuated from the ship. The captain leaves the sinking ship last.
If we cannot determine exactly who should leave the ship first for any two members of the crew by the rules from the previous paragraph, then the one who stands to the left in the line leaves the ship first (or in other words, the one whose number in the line is less).
For each crew member we know his status as a crew member, and also his name. All crew members have different names. Determine the order in which to evacuate the crew.
|
The first line contains an integer *n*, which is the number of people in the crew (1<=≤<=*n*<=≤<=100). Then follow *n* lines. The *i*-th of those lines contains two words — the name of the crew member who is *i*-th in line, and his status on the ship. The words are separated by exactly one space. There are no other spaces in the line. The names consist of Latin letters, the first letter is uppercase, the rest are lowercase. The length of any name is from 1 to 10 characters. The status can have the following values: rat for a rat, woman for a woman, child for a child, man for a man, captain for the captain. The crew contains exactly one captain.
|
Print *n* lines. The *i*-th of them should contain the name of the crew member who must be the *i*-th one to leave the ship.
|
[
"6\nJack captain\nAlice woman\nCharlie man\nTeddy rat\nBob child\nJulia woman\n"
] |
[
"Teddy\nAlice\nBob\nJulia\nCharlie\nJack\n"
] |
none
| 500
|
[
{
"input": "6\nJack captain\nAlice woman\nCharlie man\nTeddy rat\nBob child\nJulia woman",
"output": "Teddy\nAlice\nBob\nJulia\nCharlie\nJack"
},
{
"input": "1\nA captain",
"output": "A"
},
{
"input": "1\nAbcdefjhij captain",
"output": "Abcdefjhij"
},
{
"input": "5\nA captain\nB man\nD woman\nC child\nE rat",
"output": "E\nD\nC\nB\nA"
},
{
"input": "10\nCap captain\nD child\nC woman\nA woman\nE child\nMan man\nB child\nF woman\nRat rat\nRatt rat",
"output": "Rat\nRatt\nD\nC\nA\nE\nB\nF\nMan\nCap"
},
{
"input": "5\nJoyxnkypf captain\nDxssgr woman\nKeojmnpd rat\nGdv man\nHnw man",
"output": "Keojmnpd\nDxssgr\nGdv\nHnw\nJoyxnkypf"
},
{
"input": "11\nJue rat\nWyglbyphk rat\nGjlgu child\nGi man\nAttx rat\nTheorpkgx man\nYm rat\nX child\nB captain\nEnualf rat\nKktsgyuyv woman",
"output": "Jue\nWyglbyphk\nAttx\nYm\nEnualf\nGjlgu\nX\nKktsgyuyv\nGi\nTheorpkgx\nB"
},
{
"input": "22\nWswwcvvm woman\nBtmfats rat\nI rat\nOcmtsnwx man\nUrcqv rat\nYghnogt woman\nWtyfc man\nWqle child\nUjfrelpu rat\nDstixj man\nAhksnio woman\nKhkvaap woman\nSjppvwm rat\nEgdmsv rat\nDank rat\nNquicjnw rat\nLh captain\nTdyaqaqln rat\nQtj rat\nTfgwijvq rat\nNbiso child\nNqthvbf woman",
"output": "Btmfats\nI\nUrcqv\nUjfrelpu\nSjppvwm\nEgdmsv\nDank\nNquicjnw\nTdyaqaqln\nQtj\nTfgwijvq\nWswwcvvm\nYghnogt\nWqle\nAhksnio\nKhkvaap\nNbiso\nNqthvbf\nOcmtsnwx\nWtyfc\nDstixj\nLh"
},
{
"input": "36\nKqxmtwmsf child\nIze woman\nDlpr child\nK woman\nF captain\nRjwfeuhba rat\nBbv rat\nS rat\nMnmg woman\nSmzyx woman\nSr man\nQmhroracn rat\nSoqpuqock rat\nPibdq man\nIlrkrptx rat\nZaecfyqka man\nMmersfs child\nVvvocqi man\nHjeqxvq rat\nMpmb woman\nWmgu woman\nCerelmhoxi child\nA man\nDylv man\nXrdgmmtcpq woman\nXj woman\nCeh child\nOfccguo man\nNevr man\nAknkwdkq child\nBmo man\nLqo woman\nVej child\nT child\nRlijc man\nNsdtpdg woman",
"output": "Rjwfeuhba\nBbv\nS\nQmhroracn\nSoqpuqock\nIlrkrptx\nHjeqxvq\nKqxmtwmsf\nIze\nDlpr\nK\nMnmg\nSmzyx\nMmersfs\nMpmb\nWmgu\nCerelmhoxi\nXrdgmmtcpq\nXj\nCeh\nAknkwdkq\nLqo\nVej\nT\nNsdtpdg\nSr\nPibdq\nZaecfyqka\nVvvocqi\nA\nDylv\nOfccguo\nNevr\nBmo\nRlijc\nF"
},
{
"input": "2\nA captain\nB man",
"output": "B\nA"
},
{
"input": "2\nB woman\nA captain",
"output": "B\nA"
},
{
"input": "2\nX child\nY captain",
"output": "X\nY"
},
{
"input": "2\nX captain\nY rat",
"output": "Y\nX"
},
{
"input": "6\nAbdelrhman captain\nAlice woman\nCharlie man\nTeddy rat\nBob child\nJulia woman",
"output": "Teddy\nAlice\nBob\nJulia\nCharlie\nAbdelrhman"
},
{
"input": "4\nAratos captain\nMind child\nAman woman\nCarrot man",
"output": "Mind\nAman\nCarrot\nAratos"
}
] | 1,613,643,068
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 26
| 218
| 0
|
n = int(input())
l1 = []
l2 = []
l3 = []
l4 = []
for i in range(n):
s = input().split()
if s[1] == 'woman' or s[1] == 'child':
l1.append(s[0])
elif s[1] == 'man':
l2.append(s[0])
elif s[1] == 'captain':
l3.append(s[0])
else:
l4.append(s[0])
l5 = l4 + l1 + l2 + l3
for i in range(n):
print(l5[i])
|
Title: Sinking Ship
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
The ship crashed into a reef and is sinking. Now the entire crew must be evacuated. All *n* crew members have already lined up in a row (for convenience let's label them all from left to right with positive integers from 1 to *n*) and await further instructions. However, one should evacuate the crew properly, in a strict order. Specifically:
The first crew members to leave the ship are rats. Then women and children (both groups have the same priority) leave the ship. After that all men are evacuated from the ship. The captain leaves the sinking ship last.
If we cannot determine exactly who should leave the ship first for any two members of the crew by the rules from the previous paragraph, then the one who stands to the left in the line leaves the ship first (or in other words, the one whose number in the line is less).
For each crew member we know his status as a crew member, and also his name. All crew members have different names. Determine the order in which to evacuate the crew.
Input Specification:
The first line contains an integer *n*, which is the number of people in the crew (1<=≤<=*n*<=≤<=100). Then follow *n* lines. The *i*-th of those lines contains two words — the name of the crew member who is *i*-th in line, and his status on the ship. The words are separated by exactly one space. There are no other spaces in the line. The names consist of Latin letters, the first letter is uppercase, the rest are lowercase. The length of any name is from 1 to 10 characters. The status can have the following values: rat for a rat, woman for a woman, child for a child, man for a man, captain for the captain. The crew contains exactly one captain.
Output Specification:
Print *n* lines. The *i*-th of them should contain the name of the crew member who must be the *i*-th one to leave the ship.
Demo Input:
['6\nJack captain\nAlice woman\nCharlie man\nTeddy rat\nBob child\nJulia woman\n']
Demo Output:
['Teddy\nAlice\nBob\nJulia\nCharlie\nJack\n']
Note:
none
|
```python
n = int(input())
l1 = []
l2 = []
l3 = []
l4 = []
for i in range(n):
s = input().split()
if s[1] == 'woman' or s[1] == 'child':
l1.append(s[0])
elif s[1] == 'man':
l2.append(s[0])
elif s[1] == 'captain':
l3.append(s[0])
else:
l4.append(s[0])
l5 = l4 + l1 + l2 + l3
for i in range(n):
print(l5[i])
```
| 3.9455
|
178
|
A1
|
Educational Game
|
PROGRAMMING
| 1,000
|
[] | null | null |
The Smart Beaver from ABBYY began to develop a new educational game for children. The rules of the game are fairly simple and are described below.
The playing field is a sequence of *n* non-negative integers *a**i* numbered from 1 to *n*. The goal of the game is to make numbers *a*1,<=*a*2,<=...,<=*a**k* (i.e. some prefix of the sequence) equal to zero for some fixed *k* (*k*<=<<=*n*), and this should be done in the smallest possible number of moves.
One move is choosing an integer *i* (1<=≤<=*i*<=≤<=*n*) such that *a**i*<=><=0 and an integer *t* (*t*<=≥<=0) such that *i*<=+<=2*t*<=≤<=*n*. After the values of *i* and *t* have been selected, the value of *a**i* is decreased by 1, and the value of *a**i*<=+<=2*t* is increased by 1. For example, let *n*<==<=4 and *a*<==<=(1,<=0,<=1,<=2), then it is possible to make move *i*<==<=3, *t*<==<=0 and get *a*<==<=(1,<=0,<=0,<=3) or to make move *i*<==<=1, *t*<==<=1 and get *a*<==<=(0,<=0,<=2,<=2) (the only possible other move is *i*<==<=1, *t*<==<=0).
You are given *n* and the initial sequence *a**i*. The task is to calculate the minimum number of moves needed to make the first *k* elements of the original sequence equal to zero for each possible *k* (1<=≤<=*k*<=<<=*n*).
|
The first input line contains a single integer *n*. The second line contains *n* integers *a**i* (0<=≤<=*a**i*<=≤<=104), separated by single spaces.
The input limitations for getting 20 points are:
- 1<=≤<=*n*<=≤<=300
The input limitations for getting 50 points are:
- 1<=≤<=*n*<=≤<=2000
The input limitations for getting 100 points are:
- 1<=≤<=*n*<=≤<=105
|
Print exactly *n*<=-<=1 lines: the *k*-th output line must contain the minimum number of moves needed to make the first *k* elements of the original sequence *a**i* equal to zero.
Please do not use the %lld specifier to read or write 64-bit integers in С++. It is preferred to use the cin, cout streams, or the %I64d specifier.
|
[
"4\n1 0 1 2\n",
"8\n1 2 3 4 5 6 7 8\n"
] |
[
"1\n1\n3\n",
"1\n3\n6\n10\n16\n24\n40\n"
] |
none
| 20
|
[
{
"input": "4\n1 0 1 2",
"output": "1\n1\n3"
},
{
"input": "8\n1 2 3 4 5 6 7 8",
"output": "1\n3\n6\n10\n16\n24\n40"
},
{
"input": "5\n4 1 4 7 6",
"output": "4\n5\n9\n17"
},
{
"input": "9\n13 13 7 11 3 9 3 5 5",
"output": "13\n26\n33\n44\n47\n69\n79\n117"
},
{
"input": "30\n8 17 20 15 18 15 20 10 5 13 5 4 15 9 11 14 18 15 7 16 18 9 17 7 10 9 5 13 17 16",
"output": "8\n25\n45\n60\n78\n93\n113\n123\n128\n141\n146\n150\n165\n174\n185\n199\n225\n257\n284\n315\n351\n375\n423\n454\n495\n549\n634\n713\n907"
},
{
"input": "80\n72 66 82 46 44 22 63 92 71 65 5 30 45 84 29 73 9 90 25 19 26 15 12 29 33 19 85 92 91 66 83 39 100 53 20 99 11 81 26 41 36 51 21 72 28 100 34 3 24 58 11 85 73 18 4 45 90 99 42 85 26 71 58 49 76 32 88 13 40 98 57 95 20 36 70 66 75 12 54 96",
"output": "72\n138\n220\n266\n310\n332\n395\n487\n558\n623\n628\n658\n703\n787\n816\n889\n898\n988\n1013\n1032\n1058\n1073\n1085\n1114\n1147\n1166\n1251\n1343\n1434\n1500\n1583\n1622\n1722\n1775\n1795\n1894\n1905\n1986\n2012\n2053\n2089\n2140\n2161\n2233\n2261\n2361\n2395\n2398\n2431\n2579\n2615\n2719\n2818\n2851\n2867\n2941\n3064\n3182\n3309\n3486\n3603\n3740\n3881\n3969\n4250\n4549\n4775\n5037\n5231\n5465\n5627\n5929\n6460\n7029\n7478\n8085\n9075\n10211\n12070"
},
{
"input": "120\n242 524 420 973 816 432 247 666 134 849 145 366 608 930 613 315 863 628 97 109 65 704 741 314 736 17 872 971 559 648 223 771 171 327 782 837 303 393 292 339 730 834 794 868 540 251 789 893 23 305 116 220 699 863 580 992 861 393 98 253 544 171 336 207 348 496 316 285 286 727 613 616 304 811 592 916 91 554 962 950 475 473 806 510 986 254 290 351 143 710 573 949 256 216 235 246 533 177 12 764 543 689 490 386 849 694 386 693 134 416 293 589 171 76 527 324 782 661 943 134",
"output": "242\n766\n1186\n2159\n2975\n3407\n3654\n4320\n4454\n5303\n5448\n5814\n6422\n7352\n7965\n8280\n9143\n9771\n9868\n9977\n10042\n10746\n11487\n11801\n12537\n12554\n13426\n14397\n14956\n15604\n15827\n16598\n16769\n17096\n17878\n18715\n19018\n19411\n19703\n20042\n20772\n21606\n22400\n23268\n23808\n24059\n24848\n25741\n25764\n26069\n26185\n26405\n27104\n27967\n28547\n29539\n30400\n30793\n30891\n31144\n31688\n31859\n32195\n32402\n32992\n34012\n34748\n36006\n37108\n38267\n39127\n40409\n40847\n42507\n43244\n44526\n4..."
}
] | 1,659,343,528
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS1
| 12
| 92
| 1,536,000
|
n=int(input())
L=list(map(int,input().split()))
count=0
for i in range(n-1):
t=0
while i+2**(t+1)<n:
t+=1
L[i+2**t]+=L[i]
count+=L[i]
L[i]=0
print(count)
|
Title: Educational Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The Smart Beaver from ABBYY began to develop a new educational game for children. The rules of the game are fairly simple and are described below.
The playing field is a sequence of *n* non-negative integers *a**i* numbered from 1 to *n*. The goal of the game is to make numbers *a*1,<=*a*2,<=...,<=*a**k* (i.e. some prefix of the sequence) equal to zero for some fixed *k* (*k*<=<<=*n*), and this should be done in the smallest possible number of moves.
One move is choosing an integer *i* (1<=≤<=*i*<=≤<=*n*) such that *a**i*<=><=0 and an integer *t* (*t*<=≥<=0) such that *i*<=+<=2*t*<=≤<=*n*. After the values of *i* and *t* have been selected, the value of *a**i* is decreased by 1, and the value of *a**i*<=+<=2*t* is increased by 1. For example, let *n*<==<=4 and *a*<==<=(1,<=0,<=1,<=2), then it is possible to make move *i*<==<=3, *t*<==<=0 and get *a*<==<=(1,<=0,<=0,<=3) or to make move *i*<==<=1, *t*<==<=1 and get *a*<==<=(0,<=0,<=2,<=2) (the only possible other move is *i*<==<=1, *t*<==<=0).
You are given *n* and the initial sequence *a**i*. The task is to calculate the minimum number of moves needed to make the first *k* elements of the original sequence equal to zero for each possible *k* (1<=≤<=*k*<=<<=*n*).
Input Specification:
The first input line contains a single integer *n*. The second line contains *n* integers *a**i* (0<=≤<=*a**i*<=≤<=104), separated by single spaces.
The input limitations for getting 20 points are:
- 1<=≤<=*n*<=≤<=300
The input limitations for getting 50 points are:
- 1<=≤<=*n*<=≤<=2000
The input limitations for getting 100 points are:
- 1<=≤<=*n*<=≤<=105
Output Specification:
Print exactly *n*<=-<=1 lines: the *k*-th output line must contain the minimum number of moves needed to make the first *k* elements of the original sequence *a**i* equal to zero.
Please do not use the %lld specifier to read or write 64-bit integers in С++. It is preferred to use the cin, cout streams, or the %I64d specifier.
Demo Input:
['4\n1 0 1 2\n', '8\n1 2 3 4 5 6 7 8\n']
Demo Output:
['1\n1\n3\n', '1\n3\n6\n10\n16\n24\n40\n']
Note:
none
|
```python
n=int(input())
L=list(map(int,input().split()))
count=0
for i in range(n-1):
t=0
while i+2**(t+1)<n:
t+=1
L[i+2**t]+=L[i]
count+=L[i]
L[i]=0
print(count)
```
| 3
|
|
110
|
A
|
Nearly Lucky Number
|
PROGRAMMING
| 800
|
[
"implementation"
] |
A. Nearly Lucky Number
|
2
|
256
|
Petya loves lucky numbers. We all know that lucky numbers are the positive integers whose decimal representations contain only the lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Unfortunately, not all numbers are lucky. Petya calls a number nearly lucky if the number of lucky digits in it is a lucky number. He wonders whether number *n* is a nearly lucky number.
|
The only line contains an integer *n* (1<=≤<=*n*<=≤<=1018).
Please do not use the %lld specificator to read or write 64-bit numbers in С++. It is preferred to use the cin, cout streams or the %I64d specificator.
|
Print on the single line "YES" if *n* is a nearly lucky number. Otherwise, print "NO" (without the quotes).
|
[
"40047\n",
"7747774\n",
"1000000000000000000\n"
] |
[
"NO\n",
"YES\n",
"NO\n"
] |
In the first sample there are 3 lucky digits (first one and last two), so the answer is "NO".
In the second sample there are 7 lucky digits, 7 is lucky number, so the answer is "YES".
In the third sample there are no lucky digits, so the answer is "NO".
| 500
|
[
{
"input": "40047",
"output": "NO"
},
{
"input": "7747774",
"output": "YES"
},
{
"input": "1000000000000000000",
"output": "NO"
},
{
"input": "7",
"output": "NO"
},
{
"input": "4",
"output": "NO"
},
{
"input": "474404774",
"output": "NO"
},
{
"input": "4744000695826",
"output": "YES"
},
{
"input": "10000000004744744",
"output": "YES"
},
{
"input": "446486416781684178",
"output": "YES"
},
{
"input": "999999999",
"output": "NO"
},
{
"input": "7777",
"output": "YES"
},
{
"input": "87414417444",
"output": "NO"
},
{
"input": "111222333444555667",
"output": "YES"
},
{
"input": "1",
"output": "NO"
},
{
"input": "4700",
"output": "NO"
},
{
"input": "3794555488744477",
"output": "NO"
},
{
"input": "444444444444444444",
"output": "NO"
},
{
"input": "474447447774444774",
"output": "NO"
},
{
"input": "777777777777777",
"output": "NO"
},
{
"input": "34777745021000000",
"output": "NO"
},
{
"input": "963",
"output": "NO"
},
{
"input": "855474448854788540",
"output": "NO"
},
{
"input": "999999999999994744",
"output": "YES"
},
{
"input": "400000000474",
"output": "YES"
},
{
"input": "123456789123456789",
"output": "YES"
},
{
"input": "740577777584945874",
"output": "NO"
},
{
"input": "7777777",
"output": "YES"
},
{
"input": "4444000111222333",
"output": "YES"
},
{
"input": "9847745885202111",
"output": "YES"
},
{
"input": "123456000000",
"output": "NO"
},
{
"input": "4744447444444",
"output": "NO"
},
{
"input": "7477",
"output": "YES"
},
{
"input": "4747477",
"output": "YES"
},
{
"input": "777777777444444444",
"output": "NO"
}
] | 1,698,947,125
| 2,147,483,647
|
PyPy 3-64
|
COMPILATION_ERROR
|
TESTS
| 0
| 0
| 0
|
s=input()
c=0
for i in s:
if i=='4' or i=='7':
c=c+1
k=0
for i in str(c):
if i!='4' or i!='7':
print("NO")
k=1
if k=0:
print("YES")
|
Title: Nearly Lucky Number
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Petya loves lucky numbers. We all know that lucky numbers are the positive integers whose decimal representations contain only the lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Unfortunately, not all numbers are lucky. Petya calls a number nearly lucky if the number of lucky digits in it is a lucky number. He wonders whether number *n* is a nearly lucky number.
Input Specification:
The only line contains an integer *n* (1<=≤<=*n*<=≤<=1018).
Please do not use the %lld specificator to read or write 64-bit numbers in С++. It is preferred to use the cin, cout streams or the %I64d specificator.
Output Specification:
Print on the single line "YES" if *n* is a nearly lucky number. Otherwise, print "NO" (without the quotes).
Demo Input:
['40047\n', '7747774\n', '1000000000000000000\n']
Demo Output:
['NO\n', 'YES\n', 'NO\n']
Note:
In the first sample there are 3 lucky digits (first one and last two), so the answer is "NO".
In the second sample there are 7 lucky digits, 7 is lucky number, so the answer is "YES".
In the third sample there are no lucky digits, so the answer is "NO".
|
```python
s=input()
c=0
for i in s:
if i=='4' or i=='7':
c=c+1
k=0
for i in str(c):
if i!='4' or i!='7':
print("NO")
k=1
if k=0:
print("YES")
```
| -1
|
1,006
|
C
|
Three Parts of the Array
|
PROGRAMMING
| 1,200
|
[
"binary search",
"data structures",
"two pointers"
] | null | null |
You are given an array $d_1, d_2, \dots, d_n$ consisting of $n$ integer numbers.
Your task is to split this array into three parts (some of which may be empty) in such a way that each element of the array belongs to exactly one of the three parts, and each of the parts forms a consecutive contiguous subsegment (possibly, empty) of the original array.
Let the sum of elements of the first part be $sum_1$, the sum of elements of the second part be $sum_2$ and the sum of elements of the third part be $sum_3$. Among all possible ways to split the array you have to choose a way such that $sum_1 = sum_3$ and $sum_1$ is maximum possible.
More formally, if the first part of the array contains $a$ elements, the second part of the array contains $b$ elements and the third part contains $c$ elements, then:
$$sum_1 = \sum\limits_{1 \le i \le a}d_i,$$ $$sum_2 = \sum\limits_{a + 1 \le i \le a + b}d_i,$$ $$sum_3 = \sum\limits_{a + b + 1 \le i \le a + b + c}d_i.$$
The sum of an empty array is $0$.
Your task is to find a way to split the array such that $sum_1 = sum_3$ and $sum_1$ is maximum possible.
|
The first line of the input contains one integer $n$ ($1 \le n \le 2 \cdot 10^5$) — the number of elements in the array $d$.
The second line of the input contains $n$ integers $d_1, d_2, \dots, d_n$ ($1 \le d_i \le 10^9$) — the elements of the array $d$.
|
Print a single integer — the maximum possible value of $sum_1$, considering that the condition $sum_1 = sum_3$ must be met.
Obviously, at least one valid way to split the array exists (use $a=c=0$ and $b=n$).
|
[
"5\n1 3 1 1 4\n",
"5\n1 3 2 1 4\n",
"3\n4 1 2\n"
] |
[
"5\n",
"4\n",
"0\n"
] |
In the first example there is only one possible splitting which maximizes $sum_1$: $[1, 3, 1], [~], [1, 4]$.
In the second example the only way to have $sum_1=4$ is: $[1, 3], [2, 1], [4]$.
In the third example there is only one way to split the array: $[~], [4, 1, 2], [~]$.
| 0
|
[
{
"input": "5\n1 3 1 1 4",
"output": "5"
},
{
"input": "5\n1 3 2 1 4",
"output": "4"
},
{
"input": "3\n4 1 2",
"output": "0"
},
{
"input": "1\n1000000000",
"output": "0"
},
{
"input": "2\n1 1",
"output": "1"
},
{
"input": "5\n1 3 5 4 5",
"output": "9"
}
] | 1,638,743,798
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 4
| 155
| 3,993,600
|
tam = int(input())
arr = list(map(int, input().split()))
pont1 = (len(arr) - 1)//2
pont2 = pont1 + 1
sum1 = sum3 = 0
for c in range(len(arr)):
if(c <= (len(arr) - 1)//2):
sum1 += arr[c]
else:
sum3 += arr[c]
while(sum1 != sum3 and pont1 >= 0 and pont2 < len(arr)):
if(sum1 > sum3):
sum1 -= arr[pont1]
pont1 -= 1
elif(sum1 < sum3):
sum3 -= arr[pont2]
pont2 += 1
if(pont1 < 0 or pont2 > len(arr) - 1):
print(0)
else:
print(sum1)
|
Title: Three Parts of the Array
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given an array $d_1, d_2, \dots, d_n$ consisting of $n$ integer numbers.
Your task is to split this array into three parts (some of which may be empty) in such a way that each element of the array belongs to exactly one of the three parts, and each of the parts forms a consecutive contiguous subsegment (possibly, empty) of the original array.
Let the sum of elements of the first part be $sum_1$, the sum of elements of the second part be $sum_2$ and the sum of elements of the third part be $sum_3$. Among all possible ways to split the array you have to choose a way such that $sum_1 = sum_3$ and $sum_1$ is maximum possible.
More formally, if the first part of the array contains $a$ elements, the second part of the array contains $b$ elements and the third part contains $c$ elements, then:
$$sum_1 = \sum\limits_{1 \le i \le a}d_i,$$ $$sum_2 = \sum\limits_{a + 1 \le i \le a + b}d_i,$$ $$sum_3 = \sum\limits_{a + b + 1 \le i \le a + b + c}d_i.$$
The sum of an empty array is $0$.
Your task is to find a way to split the array such that $sum_1 = sum_3$ and $sum_1$ is maximum possible.
Input Specification:
The first line of the input contains one integer $n$ ($1 \le n \le 2 \cdot 10^5$) — the number of elements in the array $d$.
The second line of the input contains $n$ integers $d_1, d_2, \dots, d_n$ ($1 \le d_i \le 10^9$) — the elements of the array $d$.
Output Specification:
Print a single integer — the maximum possible value of $sum_1$, considering that the condition $sum_1 = sum_3$ must be met.
Obviously, at least one valid way to split the array exists (use $a=c=0$ and $b=n$).
Demo Input:
['5\n1 3 1 1 4\n', '5\n1 3 2 1 4\n', '3\n4 1 2\n']
Demo Output:
['5\n', '4\n', '0\n']
Note:
In the first example there is only one possible splitting which maximizes $sum_1$: $[1, 3, 1], [~], [1, 4]$.
In the second example the only way to have $sum_1=4$ is: $[1, 3], [2, 1], [4]$.
In the third example there is only one way to split the array: $[~], [4, 1, 2], [~]$.
|
```python
tam = int(input())
arr = list(map(int, input().split()))
pont1 = (len(arr) - 1)//2
pont2 = pont1 + 1
sum1 = sum3 = 0
for c in range(len(arr)):
if(c <= (len(arr) - 1)//2):
sum1 += arr[c]
else:
sum3 += arr[c]
while(sum1 != sum3 and pont1 >= 0 and pont2 < len(arr)):
if(sum1 > sum3):
sum1 -= arr[pont1]
pont1 -= 1
elif(sum1 < sum3):
sum3 -= arr[pont2]
pont2 += 1
if(pont1 < 0 or pont2 > len(arr) - 1):
print(0)
else:
print(sum1)
```
| 0
|
|
330
|
A
|
Cakeminator
|
PROGRAMMING
| 800
|
[
"brute force",
"implementation"
] | null | null |
You are given a rectangular cake, represented as an *r*<=×<=*c* grid. Each cell either has an evil strawberry, or is empty. For example, a 3<=×<=4 cake may look as follows:
The cakeminator is going to eat the cake! Each time he eats, he chooses a row or a column that does not contain any evil strawberries and contains at least one cake cell that has not been eaten before, and eats all the cake cells there. He may decide to eat any number of times.
Please output the maximum number of cake cells that the cakeminator can eat.
|
The first line contains two integers *r* and *c* (2<=≤<=*r*,<=*c*<=≤<=10), denoting the number of rows and the number of columns of the cake. The next *r* lines each contains *c* characters — the *j*-th character of the *i*-th line denotes the content of the cell at row *i* and column *j*, and is either one of these:
- '.' character denotes a cake cell with no evil strawberry; - 'S' character denotes a cake cell with an evil strawberry.
|
Output the maximum number of cake cells that the cakeminator can eat.
|
[
"3 4\nS...\n....\n..S.\n"
] |
[
"8\n"
] |
For the first example, one possible way to eat the maximum number of cake cells is as follows (perform 3 eats).
| 500
|
[
{
"input": "3 4\nS...\n....\n..S.",
"output": "8"
},
{
"input": "2 2\n..\n..",
"output": "4"
},
{
"input": "2 2\nSS\nSS",
"output": "0"
},
{
"input": "7 3\nS..\nS..\nS..\nS..\nS..\nS..\nS..",
"output": "14"
},
{
"input": "3 5\n..S..\nSSSSS\n..S..",
"output": "0"
},
{
"input": "10 10\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS",
"output": "0"
},
{
"input": "10 10\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS\nS...SSSSSS",
"output": "30"
},
{
"input": "10 10\n....S..S..\n....S..S..\n....S..S..\n....S..S..\n....S..S..\n....S..S..\n....S..S..\n....S..S..\n....S..S..\n....S..S..",
"output": "80"
},
{
"input": "9 5\nSSSSS\nSSSSS\nSSSSS\nSSSSS\nSSSSS\nSSSSS\nSSSSS\nSSSSS\nSSSSS",
"output": "0"
},
{
"input": "9 9\n...S.....\nS.S.....S\n.S....S..\n.S.....SS\n.........\n..S.S..S.\n.SS......\n....S....\n..S...S..",
"output": "17"
},
{
"input": "5 6\nSSSSSS\nSSSSSS\nSSSSSS\nSS.S..\nS.S.SS",
"output": "0"
},
{
"input": "9 8\n........\n.......S\n........\nS.......\n........\n........\nS.......\n........\n.......S",
"output": "64"
},
{
"input": "9 7\n......S\n......S\nS.S.S..\n.......\n.......\n.S.....\n.S....S\n..S....\n.S....S",
"output": "28"
},
{
"input": "10 10\n.....S....\n....SS..S.\n.S...S....\n........SS\n.S.......S\nSS..S.....\n.SS.....SS\nS..S......\n.......SSS\nSSSSS....S",
"output": "10"
},
{
"input": "6 7\n..S.SS.\n......S\n....S.S\nSS..S..\nS..SS.S\n.....S.",
"output": "0"
},
{
"input": "10 6\n.SSSSS\nSSS.SS\nSSSSSS\nS.SSSS\nSSSSS.\nS.SSSS\nSS.SSS\n.SSS.S\n.SSS..\nSS..SS",
"output": "0"
},
{
"input": "2 2\n..\n..",
"output": "4"
},
{
"input": "3 2\nS.\n.S\nS.",
"output": "0"
},
{
"input": "3 2\nS.\n.S\nS.",
"output": "0"
},
{
"input": "4 3\n.S.\nS.S\n.S.\nS.S",
"output": "0"
},
{
"input": "2 3\n...\nSSS",
"output": "3"
},
{
"input": "2 4\nS.SS\nS.SS",
"output": "2"
},
{
"input": "2 2\n..\n.S",
"output": "3"
},
{
"input": "3 2\n.S\n.S\nSS",
"output": "0"
},
{
"input": "2 4\nSS.S\n..S.",
"output": "0"
},
{
"input": "2 3\n...\nS..",
"output": "5"
}
] | 1,605,257,038
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 42
| 186
| 307,200
|
# # ----- Транспортирование 1 ----
# n = int(input())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n):
# k = []
# for j in range(n):
# k.append(a[j][i])
# print(*k)
# # ----- Транспортирование 2 ----
# n = int(input())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n - 1, -1, -1):
# k = []
# for j in range(n - 1, -1, -1):
# k.append(a[j][i])
# print(*k)
# # ----- Транспортирование 3 ----
# n, m = map(int, input().split())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# print()
# for i in range(n):
# k = []
# for j in range(m - 1, -1, -1):
# k.append(a[i][j])
# print(*k)
# # ----- Красивая матрица ----
# a = []
# for i in range(5):
# a.append(list(map(int, input().split())))
# for i in range(5):
# for j in range(5):
# if a[i][j] == 1:
# row = i
# column = j
# print(abs(2 - row) + abs(2 - column))
# # ----- Транспортирование 4 ----
# n, m = map(int, input().split())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n - 1, -1, -1):
# print(*a[i])
# # ----- Сумма главной диагонали ----
# n = int(input())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# # # -- 1st ---
# # s = 0
# # for i in range(n):
# # s += a[i][i]
# # print(s)
# # -- 2st ---
# print(sum(a[i][i] for i in range(n)))
# # ---- Двумерный массив ---
# n, m = map(int, input().split())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n):
# print(sum(i for i in a[i]), end=' ')
# print()
# for j in range(m):
# b = 0
# for i in range(n):
# b += a[i][j]
# print(b, end=' ')
# print('\n')
# for i in a:
# print(*i)
# # ---- Сумма матриц ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# input()
# b = [list(map(int, input().split())) for i in range(n)]
# for i in range(n):
# c = []
# for j in range(m):
# c.append(a[i][j] + b[i][j])
# print(*c)
# from time import *
# # ---- Произведение матриц ---
# n, m, p = map(int, input().split())
# st = time()
# a = [list(map(int, input().split())) for i in range(n)]
# # a = list()
# # for i in range(n):
# # a.append([int(j) for j in input().split()])
# input()
#
# b = [list(map(int, input().split())) for s in range(n)]
# # b = list()
# # for i in range(n):
# # b.append([int(j) for j in input().split()])
# for i in range(n):
# for k in range(p):
# pr = []
# for j in range(m):
# pr.append(a[i][j] * b[j][k])
# print(sum(pr), end=' ')
# print()
# print(time() - st)
# # ---- Семетрична ли матрица ---
# n = int(input('Size: '))
# a = [list(map(int, input().split())) for i in range(n)]
# b = []
# for i in range(n):
# c = []
# for j in range(n):
# c += [a[j][i]]
# b += [c]
# if a == b:
# print('yes')
# else:
# print('no')
# # ---- Семетрична ли матрица ---
# n = int(input())
# a = [list(map(int, input().split())) for k in range(n)]
# i = 0
# while i < n:
# for j in range(n):
# if a[i][j] != a[j][i]:
# i = n
# print('no')
# break
# if i == n - 1 and j == n - 1:
# print('yes')
# i += 1
# # --- Состязания - 1 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# sum_score = []
# for i in range(n):
# sum_score.append(sum(a[i]))
# max_score = max(sum_score)
# print(max_score, sum_score.index(max_score), sep='\n')
# # --- Состязания - 2 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# max_stroka = []
# for i in a:
# max_stroka.append(max(i))
# print(max(max_stroka))
# print(max_stroka.index(max(max_stroka)), a[max_stroka.index(max(max_stroka))].index(max(max_stroka)))
# # --- Состязания - 3 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# max_score = 0
# max_sum_stroka = 0
# igrok = 0
# for i in range(n):
# if max(a[i]) > max_score:
# max_score = max(a[i])
# max_sum_stroka = sum(a[i])
# igrok = i
# if max(a[i]) == max_score and sum(a[i]) > max_sum_stroka:
# max_sum_stroka = sum(a[i])
# igrok = i
# print(igrok)
# # --- Миша и негатив ---
# n, m = map(int, input().split())
# a = [input() for i in range(n)]
# input()
# b = [input() for i in range(n)]
# errors = 0
# for row in range(n):
# for column in range(m):
# if a[row][column] == b[row][column]:
# errors += 1
# print(errors)
# # --- A. Матчи ---
# n = int(input())
# a = [list(map(int, input().split())) for i in range(n)]
# count = 0
# for i in range(n):
# for j in range(n):
# if i != j and a[i][0] == a[j][1]:
# count += 1
# print(count)
# # --- Весёлая шутка ---
# h = input()
# g = input()
# l = input()
# hg = h + g
# letters = []
# host_gest = []
# for i in l:
# letters.append(i)
# letters.sort()
# for i in hg:
# host_gest.append(i)
# host_gest.sort()
# if host_gest == letters:
# print('YES')
# else:
# print('NO')
# # --- Состязания - 4 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# count = 0
# max_score = 0
# for i in a:
# if max(i) > max_score:
# max_score = max(i)
# count = 1
# continue
# if max(i) == max_score:
# count += 1
# print(count)
# # --- Морской бой - 2 ---
# n, m = map(int, input().split())
# mas = list()
# mas.append('.' * (m + 2))
# for i in range(n):
# row = '.' + input() + '.'
# mas.append(row)
# mas.append('.' * (m + 2))
# count = 0
# for i in range(1, n + 1):
# for j in range(1, m + 1):
# if mas[i][j] == '.' and mas[i][j + 1] == '.' and mas[i][j - 1] == '.' and mas[i + 1][j] == '.' \
# and mas[i - 1][j] == '.':
# count += 1
# print(count)
# # --- Карты ---
# n = int(input())
# a = list(map(int, input().split()))
# in_used = []
# count = sum(a) / (n / 2)
# for i in range(n - 1):
# sum_card = 0
# if i in in_used:
# continue
# for j in range(i + 1, n):
# if j in in_used:
# continue
# sum_card = a[i] + a[j]
# if sum_card == count:
# print(i + 1, j + 1)
# in_used += [i] + [j]
# break
# # --- Заполнение змейкой ---
# n, m = map(int, input().split())
# k = 0
# s = m
# for i in range(n):
# if i % 2 == 0:
# a = [j for j in range(k, s)]
# k = s
# s += m
# print(*a)
# else:
# a = [j for j in range(k, s)]
# k = s
# s += m
# a.reverse()
# print(*a)
# # --- Фотографии ---
# n, m = map(int, input().split())
# a = ''
# for i in range(n):
# a += input().replace(' ', '')
# if 'C' in a or 'M' in a or 'Y' in a:
# print('#Color')
# else:
# print('#Black&White')
# # --- Спираль ---
# n = int(input())
# mas = list([0] * n for i in range(n))
# x = 0
# y = -1
# move_x = 0
# move_y = 1
# number = 1
# while number <= n ** 2:
# if 0 <= x + move_x < n and 0 <= y + move_y < n and mas[x + move_x][y + move_y] == 0:
# x += move_x
# y += move_y
# mas[x][y] = number
# number += 1
# else:
# if move_y == 1:
# move_x = 1
# move_y = 0
# elif move_x == 1:
# move_x = 0
# move_y = -1
# elif move_y == -1:
# move_x = -1
# move_y = 0
# elif move_x == -1:
# move_x = 0
# move_y = 1
# for row in mas:
# print(*row)
# # --- Спираль (моё решение) ---
# n = int(input())
# mas = list([0] * n for i in range(n))
# x = 0
# y = -1
# k = 1
# while n > 0:
# for y in range(y + 1, y + 1 + n):
# mas[x][y] = k
# k += 1
# for x in range(x + 1, x + n):
# mas[x][y] = k
# k += 1
# n -= 1
# for y in range(y - 1, y - 1 - n, -1):
# mas[x][y] = k
# k += 1
# n -= 1
# for x in range(x - 1, x - 1 - n, -1):
# mas[x][y] = k
# k += 1
# for row in mas:
# print(*row)
# # print('\t'.join(map(str, row)))
# #n - размерность матрицы n x n
# #mat - результирующая матрица
# #st - текущее значение-счетчик для записи в матрицу
# #m - коеффициент, используемый для заполнения верхней
# #матрицы последующих витков, т.к. одномерные матрицы
# #следующих витков имеют меньше значений
# n = int(input())
# mat = [[0]*n for i in range(n)]
# st, m = 1, 0
# # Заранее присваиваю значение центральному элементу
# # матрицы
# mat[n//2][n//2]=n*n
# for v in range(n//2):
# #Заполнение верхней горизонтальной матрицы
# for i in range(n-m):
# mat[v][i+v] = st
# st+=1
# #i+=1
# #Заполнение правой вертикальной матрицы
# for i in range(v+1, n-v):
# mat[i][-v-1] = st
# st+=1
# #i+=1
# #Заполнение нижней горизонтальной матрицы
# for i in range(v+1, n-v):
# mat[-v-1][-i-1] =st
# st+=1
# #i+=1
# #Заполнение левой вертикальной матрицы
# for i in range(v+1, n-(v+1)):
# mat[-i-1][v]=st
# st+=1
# #i+=1
# #v+=1
# m+=2
# #Вывод результата на экран
# for i in mat:
# print(*i)
# --- Тортминатор ---
n, m = map(int, input().split())
st = [input() for _ in range(n)]
col = []
for j in range(m):
a = ''
for i in range(n):
a += st[i][j:j + 1]
col.append(a)
count = 0
count_st = 0
for i in range(n):
if 'S' not in st[i]:
count += m
count_st += 1
for j in range(m):
if 'S' not in col[j]:
count += n - count_st
print(count)
|
Title: Cakeminator
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given a rectangular cake, represented as an *r*<=×<=*c* grid. Each cell either has an evil strawberry, or is empty. For example, a 3<=×<=4 cake may look as follows:
The cakeminator is going to eat the cake! Each time he eats, he chooses a row or a column that does not contain any evil strawberries and contains at least one cake cell that has not been eaten before, and eats all the cake cells there. He may decide to eat any number of times.
Please output the maximum number of cake cells that the cakeminator can eat.
Input Specification:
The first line contains two integers *r* and *c* (2<=≤<=*r*,<=*c*<=≤<=10), denoting the number of rows and the number of columns of the cake. The next *r* lines each contains *c* characters — the *j*-th character of the *i*-th line denotes the content of the cell at row *i* and column *j*, and is either one of these:
- '.' character denotes a cake cell with no evil strawberry; - 'S' character denotes a cake cell with an evil strawberry.
Output Specification:
Output the maximum number of cake cells that the cakeminator can eat.
Demo Input:
['3 4\nS...\n....\n..S.\n']
Demo Output:
['8\n']
Note:
For the first example, one possible way to eat the maximum number of cake cells is as follows (perform 3 eats).
|
```python
# # ----- Транспортирование 1 ----
# n = int(input())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n):
# k = []
# for j in range(n):
# k.append(a[j][i])
# print(*k)
# # ----- Транспортирование 2 ----
# n = int(input())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n - 1, -1, -1):
# k = []
# for j in range(n - 1, -1, -1):
# k.append(a[j][i])
# print(*k)
# # ----- Транспортирование 3 ----
# n, m = map(int, input().split())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# print()
# for i in range(n):
# k = []
# for j in range(m - 1, -1, -1):
# k.append(a[i][j])
# print(*k)
# # ----- Красивая матрица ----
# a = []
# for i in range(5):
# a.append(list(map(int, input().split())))
# for i in range(5):
# for j in range(5):
# if a[i][j] == 1:
# row = i
# column = j
# print(abs(2 - row) + abs(2 - column))
# # ----- Транспортирование 4 ----
# n, m = map(int, input().split())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n - 1, -1, -1):
# print(*a[i])
# # ----- Сумма главной диагонали ----
# n = int(input())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# # # -- 1st ---
# # s = 0
# # for i in range(n):
# # s += a[i][i]
# # print(s)
# # -- 2st ---
# print(sum(a[i][i] for i in range(n)))
# # ---- Двумерный массив ---
# n, m = map(int, input().split())
# a = []
# for i in range(n):
# a.append(list(map(int, input().split())))
# for i in range(n):
# print(sum(i for i in a[i]), end=' ')
# print()
# for j in range(m):
# b = 0
# for i in range(n):
# b += a[i][j]
# print(b, end=' ')
# print('\n')
# for i in a:
# print(*i)
# # ---- Сумма матриц ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# input()
# b = [list(map(int, input().split())) for i in range(n)]
# for i in range(n):
# c = []
# for j in range(m):
# c.append(a[i][j] + b[i][j])
# print(*c)
# from time import *
# # ---- Произведение матриц ---
# n, m, p = map(int, input().split())
# st = time()
# a = [list(map(int, input().split())) for i in range(n)]
# # a = list()
# # for i in range(n):
# # a.append([int(j) for j in input().split()])
# input()
#
# b = [list(map(int, input().split())) for s in range(n)]
# # b = list()
# # for i in range(n):
# # b.append([int(j) for j in input().split()])
# for i in range(n):
# for k in range(p):
# pr = []
# for j in range(m):
# pr.append(a[i][j] * b[j][k])
# print(sum(pr), end=' ')
# print()
# print(time() - st)
# # ---- Семетрична ли матрица ---
# n = int(input('Size: '))
# a = [list(map(int, input().split())) for i in range(n)]
# b = []
# for i in range(n):
# c = []
# for j in range(n):
# c += [a[j][i]]
# b += [c]
# if a == b:
# print('yes')
# else:
# print('no')
# # ---- Семетрична ли матрица ---
# n = int(input())
# a = [list(map(int, input().split())) for k in range(n)]
# i = 0
# while i < n:
# for j in range(n):
# if a[i][j] != a[j][i]:
# i = n
# print('no')
# break
# if i == n - 1 and j == n - 1:
# print('yes')
# i += 1
# # --- Состязания - 1 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# sum_score = []
# for i in range(n):
# sum_score.append(sum(a[i]))
# max_score = max(sum_score)
# print(max_score, sum_score.index(max_score), sep='\n')
# # --- Состязания - 2 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# max_stroka = []
# for i in a:
# max_stroka.append(max(i))
# print(max(max_stroka))
# print(max_stroka.index(max(max_stroka)), a[max_stroka.index(max(max_stroka))].index(max(max_stroka)))
# # --- Состязания - 3 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# max_score = 0
# max_sum_stroka = 0
# igrok = 0
# for i in range(n):
# if max(a[i]) > max_score:
# max_score = max(a[i])
# max_sum_stroka = sum(a[i])
# igrok = i
# if max(a[i]) == max_score and sum(a[i]) > max_sum_stroka:
# max_sum_stroka = sum(a[i])
# igrok = i
# print(igrok)
# # --- Миша и негатив ---
# n, m = map(int, input().split())
# a = [input() for i in range(n)]
# input()
# b = [input() for i in range(n)]
# errors = 0
# for row in range(n):
# for column in range(m):
# if a[row][column] == b[row][column]:
# errors += 1
# print(errors)
# # --- A. Матчи ---
# n = int(input())
# a = [list(map(int, input().split())) for i in range(n)]
# count = 0
# for i in range(n):
# for j in range(n):
# if i != j and a[i][0] == a[j][1]:
# count += 1
# print(count)
# # --- Весёлая шутка ---
# h = input()
# g = input()
# l = input()
# hg = h + g
# letters = []
# host_gest = []
# for i in l:
# letters.append(i)
# letters.sort()
# for i in hg:
# host_gest.append(i)
# host_gest.sort()
# if host_gest == letters:
# print('YES')
# else:
# print('NO')
# # --- Состязания - 4 ---
# n, m = map(int, input().split())
# a = [list(map(int, input().split())) for i in range(n)]
# count = 0
# max_score = 0
# for i in a:
# if max(i) > max_score:
# max_score = max(i)
# count = 1
# continue
# if max(i) == max_score:
# count += 1
# print(count)
# # --- Морской бой - 2 ---
# n, m = map(int, input().split())
# mas = list()
# mas.append('.' * (m + 2))
# for i in range(n):
# row = '.' + input() + '.'
# mas.append(row)
# mas.append('.' * (m + 2))
# count = 0
# for i in range(1, n + 1):
# for j in range(1, m + 1):
# if mas[i][j] == '.' and mas[i][j + 1] == '.' and mas[i][j - 1] == '.' and mas[i + 1][j] == '.' \
# and mas[i - 1][j] == '.':
# count += 1
# print(count)
# # --- Карты ---
# n = int(input())
# a = list(map(int, input().split()))
# in_used = []
# count = sum(a) / (n / 2)
# for i in range(n - 1):
# sum_card = 0
# if i in in_used:
# continue
# for j in range(i + 1, n):
# if j in in_used:
# continue
# sum_card = a[i] + a[j]
# if sum_card == count:
# print(i + 1, j + 1)
# in_used += [i] + [j]
# break
# # --- Заполнение змейкой ---
# n, m = map(int, input().split())
# k = 0
# s = m
# for i in range(n):
# if i % 2 == 0:
# a = [j for j in range(k, s)]
# k = s
# s += m
# print(*a)
# else:
# a = [j for j in range(k, s)]
# k = s
# s += m
# a.reverse()
# print(*a)
# # --- Фотографии ---
# n, m = map(int, input().split())
# a = ''
# for i in range(n):
# a += input().replace(' ', '')
# if 'C' in a or 'M' in a or 'Y' in a:
# print('#Color')
# else:
# print('#Black&White')
# # --- Спираль ---
# n = int(input())
# mas = list([0] * n for i in range(n))
# x = 0
# y = -1
# move_x = 0
# move_y = 1
# number = 1
# while number <= n ** 2:
# if 0 <= x + move_x < n and 0 <= y + move_y < n and mas[x + move_x][y + move_y] == 0:
# x += move_x
# y += move_y
# mas[x][y] = number
# number += 1
# else:
# if move_y == 1:
# move_x = 1
# move_y = 0
# elif move_x == 1:
# move_x = 0
# move_y = -1
# elif move_y == -1:
# move_x = -1
# move_y = 0
# elif move_x == -1:
# move_x = 0
# move_y = 1
# for row in mas:
# print(*row)
# # --- Спираль (моё решение) ---
# n = int(input())
# mas = list([0] * n for i in range(n))
# x = 0
# y = -1
# k = 1
# while n > 0:
# for y in range(y + 1, y + 1 + n):
# mas[x][y] = k
# k += 1
# for x in range(x + 1, x + n):
# mas[x][y] = k
# k += 1
# n -= 1
# for y in range(y - 1, y - 1 - n, -1):
# mas[x][y] = k
# k += 1
# n -= 1
# for x in range(x - 1, x - 1 - n, -1):
# mas[x][y] = k
# k += 1
# for row in mas:
# print(*row)
# # print('\t'.join(map(str, row)))
# #n - размерность матрицы n x n
# #mat - результирующая матрица
# #st - текущее значение-счетчик для записи в матрицу
# #m - коеффициент, используемый для заполнения верхней
# #матрицы последующих витков, т.к. одномерные матрицы
# #следующих витков имеют меньше значений
# n = int(input())
# mat = [[0]*n for i in range(n)]
# st, m = 1, 0
# # Заранее присваиваю значение центральному элементу
# # матрицы
# mat[n//2][n//2]=n*n
# for v in range(n//2):
# #Заполнение верхней горизонтальной матрицы
# for i in range(n-m):
# mat[v][i+v] = st
# st+=1
# #i+=1
# #Заполнение правой вертикальной матрицы
# for i in range(v+1, n-v):
# mat[i][-v-1] = st
# st+=1
# #i+=1
# #Заполнение нижней горизонтальной матрицы
# for i in range(v+1, n-v):
# mat[-v-1][-i-1] =st
# st+=1
# #i+=1
# #Заполнение левой вертикальной матрицы
# for i in range(v+1, n-(v+1)):
# mat[-i-1][v]=st
# st+=1
# #i+=1
# #v+=1
# m+=2
# #Вывод результата на экран
# for i in mat:
# print(*i)
# --- Тортминатор ---
n, m = map(int, input().split())
st = [input() for _ in range(n)]
col = []
for j in range(m):
a = ''
for i in range(n):
a += st[i][j:j + 1]
col.append(a)
count = 0
count_st = 0
for i in range(n):
if 'S' not in st[i]:
count += m
count_st += 1
for j in range(m):
if 'S' not in col[j]:
count += n - count_st
print(count)
```
| 3
|
|
733
|
B
|
Parade
|
PROGRAMMING
| 1,100
|
[
"math"
] | null | null |
Very soon there will be a parade of victory over alien invaders in Berland. Unfortunately, all soldiers died in the war and now the army consists of entirely new recruits, many of whom do not even know from which leg they should begin to march. The civilian population also poorly understands from which leg recruits begin to march, so it is only important how many soldiers march in step.
There will be *n* columns participating in the parade, the *i*-th column consists of *l**i* soldiers, who start to march from left leg, and *r**i* soldiers, who start to march from right leg.
The beauty of the parade is calculated by the following formula: if *L* is the total number of soldiers on the parade who start to march from the left leg, and *R* is the total number of soldiers on the parade who start to march from the right leg, so the beauty will equal |*L*<=-<=*R*|.
No more than once you can choose one column and tell all the soldiers in this column to switch starting leg, i.e. everyone in this columns who starts the march from left leg will now start it from right leg, and vice versa. Formally, you can pick no more than one index *i* and swap values *l**i* and *r**i*.
Find the index of the column, such that switching the starting leg for soldiers in it will maximize the the beauty of the parade, or determine, that no such operation can increase the current beauty.
|
The first line contains single integer *n* (1<=≤<=*n*<=≤<=105) — the number of columns.
The next *n* lines contain the pairs of integers *l**i* and *r**i* (1<=≤<=*l**i*,<=*r**i*<=≤<=500) — the number of soldiers in the *i*-th column which start to march from the left or the right leg respectively.
|
Print single integer *k* — the number of the column in which soldiers need to change the leg from which they start to march, or 0 if the maximum beauty is already reached.
Consider that columns are numbered from 1 to *n* in the order they are given in the input data.
If there are several answers, print any of them.
|
[
"3\n5 6\n8 9\n10 3\n",
"2\n6 5\n5 6\n",
"6\n5 9\n1 3\n4 8\n4 5\n23 54\n12 32\n"
] |
[
"3\n",
"1\n",
"0\n"
] |
In the first example if you don't give the order to change the leg, the number of soldiers, who start to march from the left leg, would equal 5 + 8 + 10 = 23, and from the right leg — 6 + 9 + 3 = 18. In this case the beauty of the parade will equal |23 - 18| = 5.
If you give the order to change the leg to the third column, so the number of soldiers, who march from the left leg, will equal 5 + 8 + 3 = 16, and who march from the right leg — 6 + 9 + 10 = 25. In this case the beauty equals |16 - 25| = 9.
It is impossible to reach greater beauty by giving another orders. Thus, the maximum beauty that can be achieved is 9.
| 1,000
|
[
{
"input": "3\n5 6\n8 9\n10 3",
"output": "3"
},
{
"input": "2\n6 5\n5 6",
"output": "1"
},
{
"input": "6\n5 9\n1 3\n4 8\n4 5\n23 54\n12 32",
"output": "0"
},
{
"input": "2\n500 499\n500 500",
"output": "0"
},
{
"input": "1\n139 252",
"output": "0"
},
{
"input": "10\n18 18\n71 471\n121 362\n467 107\n138 254\n13 337\n499 373\n337 387\n147 417\n76 417",
"output": "4"
},
{
"input": "4\n4 1\n5 3\n7 6\n3 5",
"output": "4"
},
{
"input": "3\n6 5\n9 8\n3 10",
"output": "3"
},
{
"input": "3\n100 9\n1 3\n1 5",
"output": "1"
},
{
"input": "4\n10 1\n10 2\n10 3\n1 10",
"output": "4"
},
{
"input": "5\n25 1\n24 1\n2 3\n2 3\n2 3",
"output": "3"
},
{
"input": "3\n90 1\n1 90\n100 1",
"output": "2"
},
{
"input": "3\n1 123\n22 1\n12 1",
"output": "1"
},
{
"input": "3\n4 5\n7 6\n10 9",
"output": "1"
},
{
"input": "4\n50 1\n50 1\n50 1\n1 49",
"output": "4"
},
{
"input": "7\n2 1\n2 1\n2 1\n2 1\n1 200\n1 200\n1 200",
"output": "1"
},
{
"input": "5\n10 8\n7 6\n2 8\n9 1\n7 1",
"output": "3"
},
{
"input": "3\n22 1\n12 1\n1 123",
"output": "3"
},
{
"input": "3\n10 8\n9 7\n4 5",
"output": "3"
},
{
"input": "5\n1 2\n4 8\n4 8\n32 16\n128 64",
"output": "2"
},
{
"input": "5\n10 1\n10 1\n10 1\n100 1\n1 5",
"output": "5"
}
] | 1,666,385,661
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 40
| 265
| 1,638,400
|
# legs
num_columns = int(input())
col_values = [0] * num_columns
total_beauty = 0
most_lefty_converts = 0
most_lefty_converts_index = -1
most_righty_converts = 0
most_righty_converts_index = -1
for c in range(num_columns):
left, right = [int(i) for i in input().split()]
column_beauty = -left + right
col_values[c] = column_beauty
total_beauty += column_beauty
lefty_converts = right - left
if lefty_converts > most_lefty_converts:
most_lefty_converts = lefty_converts
most_lefty_converts_index = c
righty_converts = left - right
if righty_converts > most_righty_converts:
most_righty_converts = righty_converts
most_righty_converts_index = c
#print("MLC:",most_lefty_converts,"index:", most_lefty_converts_index)
#print("MRC:",most_righty_converts,"index:", most_righty_converts_index)
abs_beauty = abs(total_beauty)
bR = abs(total_beauty + 2*most_righty_converts)
bL = abs(total_beauty - 2*most_lefty_converts)
#print("bR:", bR, "bL:", bL)
if abs_beauty > bR and abs_beauty > bL:
print(0)
elif bR > bL:
print(most_righty_converts_index+1)
elif bL > bR:
print(most_lefty_converts_index+1)
elif bL == bR:
print(most_righty_converts_index+1)
#print("B:", total_beauty)
|
Title: Parade
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Very soon there will be a parade of victory over alien invaders in Berland. Unfortunately, all soldiers died in the war and now the army consists of entirely new recruits, many of whom do not even know from which leg they should begin to march. The civilian population also poorly understands from which leg recruits begin to march, so it is only important how many soldiers march in step.
There will be *n* columns participating in the parade, the *i*-th column consists of *l**i* soldiers, who start to march from left leg, and *r**i* soldiers, who start to march from right leg.
The beauty of the parade is calculated by the following formula: if *L* is the total number of soldiers on the parade who start to march from the left leg, and *R* is the total number of soldiers on the parade who start to march from the right leg, so the beauty will equal |*L*<=-<=*R*|.
No more than once you can choose one column and tell all the soldiers in this column to switch starting leg, i.e. everyone in this columns who starts the march from left leg will now start it from right leg, and vice versa. Formally, you can pick no more than one index *i* and swap values *l**i* and *r**i*.
Find the index of the column, such that switching the starting leg for soldiers in it will maximize the the beauty of the parade, or determine, that no such operation can increase the current beauty.
Input Specification:
The first line contains single integer *n* (1<=≤<=*n*<=≤<=105) — the number of columns.
The next *n* lines contain the pairs of integers *l**i* and *r**i* (1<=≤<=*l**i*,<=*r**i*<=≤<=500) — the number of soldiers in the *i*-th column which start to march from the left or the right leg respectively.
Output Specification:
Print single integer *k* — the number of the column in which soldiers need to change the leg from which they start to march, or 0 if the maximum beauty is already reached.
Consider that columns are numbered from 1 to *n* in the order they are given in the input data.
If there are several answers, print any of them.
Demo Input:
['3\n5 6\n8 9\n10 3\n', '2\n6 5\n5 6\n', '6\n5 9\n1 3\n4 8\n4 5\n23 54\n12 32\n']
Demo Output:
['3\n', '1\n', '0\n']
Note:
In the first example if you don't give the order to change the leg, the number of soldiers, who start to march from the left leg, would equal 5 + 8 + 10 = 23, and from the right leg — 6 + 9 + 3 = 18. In this case the beauty of the parade will equal |23 - 18| = 5.
If you give the order to change the leg to the third column, so the number of soldiers, who march from the left leg, will equal 5 + 8 + 3 = 16, and who march from the right leg — 6 + 9 + 10 = 25. In this case the beauty equals |16 - 25| = 9.
It is impossible to reach greater beauty by giving another orders. Thus, the maximum beauty that can be achieved is 9.
|
```python
# legs
num_columns = int(input())
col_values = [0] * num_columns
total_beauty = 0
most_lefty_converts = 0
most_lefty_converts_index = -1
most_righty_converts = 0
most_righty_converts_index = -1
for c in range(num_columns):
left, right = [int(i) for i in input().split()]
column_beauty = -left + right
col_values[c] = column_beauty
total_beauty += column_beauty
lefty_converts = right - left
if lefty_converts > most_lefty_converts:
most_lefty_converts = lefty_converts
most_lefty_converts_index = c
righty_converts = left - right
if righty_converts > most_righty_converts:
most_righty_converts = righty_converts
most_righty_converts_index = c
#print("MLC:",most_lefty_converts,"index:", most_lefty_converts_index)
#print("MRC:",most_righty_converts,"index:", most_righty_converts_index)
abs_beauty = abs(total_beauty)
bR = abs(total_beauty + 2*most_righty_converts)
bL = abs(total_beauty - 2*most_lefty_converts)
#print("bR:", bR, "bL:", bL)
if abs_beauty > bR and abs_beauty > bL:
print(0)
elif bR > bL:
print(most_righty_converts_index+1)
elif bL > bR:
print(most_lefty_converts_index+1)
elif bL == bR:
print(most_righty_converts_index+1)
#print("B:", total_beauty)
```
| 3
|
|
445
|
A
|
DZY Loves Chessboard
|
PROGRAMMING
| 1,200
|
[
"dfs and similar",
"implementation"
] | null | null |
DZY loves chessboard, and he enjoys playing with it.
He has a chessboard of *n* rows and *m* columns. Some cells of the chessboard are bad, others are good. For every good cell, DZY wants to put a chessman on it. Each chessman is either white or black. After putting all chessmen, DZY wants that no two chessmen with the same color are on two adjacent cells. Two cells are adjacent if and only if they share a common edge.
You task is to find any suitable placement of chessmen on the given chessboard.
|
The first line contains two space-separated integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100).
Each of the next *n* lines contains a string of *m* characters: the *j*-th character of the *i*-th string is either "." or "-". A "." means that the corresponding cell (in the *i*-th row and the *j*-th column) is good, while a "-" means it is bad.
|
Output must contain *n* lines, each line must contain a string of *m* characters. The *j*-th character of the *i*-th string should be either "W", "B" or "-". Character "W" means the chessman on the cell is white, "B" means it is black, "-" means the cell is a bad cell.
If multiple answers exist, print any of them. It is guaranteed that at least one answer exists.
|
[
"1 1\n.\n",
"2 2\n..\n..\n",
"3 3\n.-.\n---\n--."
] |
[
"B\n",
"BW\nWB\n",
"B-B\n---\n--B"
] |
In the first sample, DZY puts a single black chessman. Of course putting a white one is also OK.
In the second sample, all 4 cells are good. No two same chessmen share an edge in the sample output.
In the third sample, no good cells are adjacent. So you can just put 3 chessmen, no matter what their colors are.
| 500
|
[
{
"input": "1 1\n.",
"output": "B"
},
{
"input": "2 2\n..\n..",
"output": "BW\nWB"
},
{
"input": "3 3\n.-.\n---\n--.",
"output": "B-B\n---\n--B"
},
{
"input": "3 1\n-\n.\n.",
"output": "-\nW\nB"
},
{
"input": "11 11\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------",
"output": "-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------\n-----------"
},
{
"input": "1 1\n-",
"output": "-"
},
{
"input": "4 2\n..\n..\n..\n..",
"output": "BW\nWB\nBW\nWB"
},
{
"input": "5 1\n.\n.\n.\n.\n.",
"output": "B\nW\nB\nW\nB"
}
] | 1,622,187,257
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 4
| 93
| 921,600
|
def fillgoodpositions(positions,n,m):
for i in range(n):
for j in range(m):
if positions[i][j]=='.':
positions[i][j] = 'W'
def properpositioning(positions,n,m):
if (n,m)==(1,1):
return
elif n==1:
for i in range(m-1):
if positions[0][i]!='-' and positions[0][i+1]!='-':
if positions[0][i]==positions[0][i+1]:
positions[0][i+1]='B'
return
elif m==1:
for j in range(n-1):
if positions[j][0]!='-' and positions[j+1][0]!='-':
if positions[j][0]==positions[j+1][0]:
positions[j+1][0]='B'
return
for i in range(n):
for j in range(m):
if positions[i][j]=='-':
continue
elif i==0 and j==0:
if (positions[i+1][j]=='W' and positions[i][j+1]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='-') or (positions[i+1][j]=='-' and positions[i][j+1]=='W'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i][j+1]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='B'):
positions[i+1][j]='B'
positions[i][j+1]='B'
elif i==0 and j==m-1:
if (positions[i][j-1]=='W' and positions[i+1][j]=='W') or (positions[i][j-1]=='W' and positions[i+1][j]=='-') or (positions[i][j-1]=='-' and positions[i+1][j]=='W'):
positions[i][j]='B'
elif (positions[i][j-1]=='B' and positions[i+1][j]!='-') or (positions[i][j-1]!='-' and positions[i+1][j]!='B'):
positions[i+1][j]='B'
positions[i][j-1]='B'
elif i==0:
if (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i][j+1]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]=='B' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]!='-' and positions[i][j-1]=='B'):
positions[i+1][j]='B'
positions[i][j+1]='B'
positions[i-1][j]='B'
elif j==0 and i==n-1:
if (positions[i-1][j]=='W' and positions[i][j+1]=='W') or (positions[i-1][j]=='W' and positions[i][j+1]=='-') or (positions[i-1][j]=='-' and positions[i][j+1]=='W'):
positions[i][j]='B'
elif (positions[i-1][j]=='B' and positions[i][j+1]!='-') or (positions[i-1][j]!='-' and positions[i][j+1]=='B'):
positions[i-1][j]='B'
positions[i][j+1]='B'
elif j==0:
if (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i-1][j]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i-1][j]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i-1][j]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i-1][j]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='-' and positions[i-1][j]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i-1][j]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i-1][j]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i][j+1]!='-' and positions[i-1][j]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]=='B' and positions[i-1][j]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]!='-' and positions[i-1][j]!='B'):
positions[i+1][j]='B'
positions[i][j+1]='B'
positions[i-1][j]='B'
elif i==n-1 and j==m-1:
if (positions[i-1][j]=='W' and positions[i][j-1]=='W') or (positions[i-1][j]=='-' and positions[i][j-1]=='W') or (positions[i-1][j]=='W' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i-1][j]=='B' and positions[i][j-1]!='-') or (positions[i-1][j]!='-' and positions[i][j-1]=='B'):
positions[i-1][j]='B'
positions[i][j-1]='B'
elif i==n-1:
if (positions[i][j+1]=='W' and positions[i][j-1]=='W' and positions[i-1][j]=='W') or (positions[i][j+1]=='-' and positions[i][j-1]=='W' and positions[i-1][j]=='W') or (positions[i][j+1]=='W' and positions[i][j-1]=='-' and positions[i-1][j]=='W') or (positions[i][j+1]=='W' and positions[i][j-1]=='W' and positions[i-1][j]=='-') or (positions[i][j+1]=='-' and positions[i][j-1]=='-' and positions[i-1][j]=='W') or (positions[i][j+1]=='-' and positions[i][j-1]=='W' and positions[i-1][j]=='-') or (positions[i][j+1]=='W' and positions[i][j-1]=='-' and positions[i-1][j]=='-'):
positions[i][j]='B'
elif (positions[i][j+1]=='B' and positions[i][j-1]!='-' and positions[i-1][j]!='-') or (positions[i][j+1]!='-' and positions[i][j-1]=='B' and positions[i-1][j]!='-') or (positions[i][j+1]!='-' and positions[i][j-1]!='-' and positions[i-1][j]=='B'):
positions[i][j+1]='B'
positions[i][j-1]='B'
positions[i-1][j]='B'
elif j==m-1:
if (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i-1][j]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]=='B' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]!='-' and positions[i][j-1]=='B'):
positions[i+1][j]='B'
positions[i-1][j]='B'
positions[i][j-1]='B'
else:
if (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i-1][j]!='-' and positions[i][j+1]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]=='B' and positions[i][j+1]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]!='-' and positions[i][j+1]=='B' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]!='-' and positions[i][j+1]!='-' and positions[i][j-1]=='B'):
positions[i+1][j]='B'
positions[i-1][j]='B'
positions[i][j+1]='B'
positions[i][j-1]='B'
n,m = input().split()
n,m = (int(n),int(m))
positions = [list(input()) for _ in range(n)]
fillgoodpositions(positions,n,m)
properpositioning(positions,n,m)
for i in range(n):
for j in range(m):
if j==m-1:
print(positions[i][j])
break
print(positions[i][j],end='')
|
Title: DZY Loves Chessboard
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
DZY loves chessboard, and he enjoys playing with it.
He has a chessboard of *n* rows and *m* columns. Some cells of the chessboard are bad, others are good. For every good cell, DZY wants to put a chessman on it. Each chessman is either white or black. After putting all chessmen, DZY wants that no two chessmen with the same color are on two adjacent cells. Two cells are adjacent if and only if they share a common edge.
You task is to find any suitable placement of chessmen on the given chessboard.
Input Specification:
The first line contains two space-separated integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100).
Each of the next *n* lines contains a string of *m* characters: the *j*-th character of the *i*-th string is either "." or "-". A "." means that the corresponding cell (in the *i*-th row and the *j*-th column) is good, while a "-" means it is bad.
Output Specification:
Output must contain *n* lines, each line must contain a string of *m* characters. The *j*-th character of the *i*-th string should be either "W", "B" or "-". Character "W" means the chessman on the cell is white, "B" means it is black, "-" means the cell is a bad cell.
If multiple answers exist, print any of them. It is guaranteed that at least one answer exists.
Demo Input:
['1 1\n.\n', '2 2\n..\n..\n', '3 3\n.-.\n---\n--.']
Demo Output:
['B\n', 'BW\nWB\n', 'B-B\n---\n--B']
Note:
In the first sample, DZY puts a single black chessman. Of course putting a white one is also OK.
In the second sample, all 4 cells are good. No two same chessmen share an edge in the sample output.
In the third sample, no good cells are adjacent. So you can just put 3 chessmen, no matter what their colors are.
|
```python
def fillgoodpositions(positions,n,m):
for i in range(n):
for j in range(m):
if positions[i][j]=='.':
positions[i][j] = 'W'
def properpositioning(positions,n,m):
if (n,m)==(1,1):
return
elif n==1:
for i in range(m-1):
if positions[0][i]!='-' and positions[0][i+1]!='-':
if positions[0][i]==positions[0][i+1]:
positions[0][i+1]='B'
return
elif m==1:
for j in range(n-1):
if positions[j][0]!='-' and positions[j+1][0]!='-':
if positions[j][0]==positions[j+1][0]:
positions[j+1][0]='B'
return
for i in range(n):
for j in range(m):
if positions[i][j]=='-':
continue
elif i==0 and j==0:
if (positions[i+1][j]=='W' and positions[i][j+1]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='-') or (positions[i+1][j]=='-' and positions[i][j+1]=='W'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i][j+1]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='B'):
positions[i+1][j]='B'
positions[i][j+1]='B'
elif i==0 and j==m-1:
if (positions[i][j-1]=='W' and positions[i+1][j]=='W') or (positions[i][j-1]=='W' and positions[i+1][j]=='-') or (positions[i][j-1]=='-' and positions[i+1][j]=='W'):
positions[i][j]='B'
elif (positions[i][j-1]=='B' and positions[i+1][j]!='-') or (positions[i][j-1]!='-' and positions[i+1][j]!='B'):
positions[i+1][j]='B'
positions[i][j-1]='B'
elif i==0:
if (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i][j+1]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]=='B' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]!='-' and positions[i][j-1]=='B'):
positions[i+1][j]='B'
positions[i][j+1]='B'
positions[i-1][j]='B'
elif j==0 and i==n-1:
if (positions[i-1][j]=='W' and positions[i][j+1]=='W') or (positions[i-1][j]=='W' and positions[i][j+1]=='-') or (positions[i-1][j]=='-' and positions[i][j+1]=='W'):
positions[i][j]='B'
elif (positions[i-1][j]=='B' and positions[i][j+1]!='-') or (positions[i-1][j]!='-' and positions[i][j+1]=='B'):
positions[i-1][j]='B'
positions[i][j+1]='B'
elif j==0:
if (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i-1][j]=='W') or (positions[i+1][j]=='W' and positions[i][j+1]=='W' and positions[i-1][j]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i-1][j]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i-1][j]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='-' and positions[i-1][j]=='W') or (positions[i+1][j]=='-' and positions[i][j+1]=='W' and positions[i-1][j]=='-') or (positions[i+1][j]=='W' and positions[i][j+1]=='-' and positions[i-1][j]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i][j+1]!='-' and positions[i-1][j]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]=='B' and positions[i-1][j]!='-') or (positions[i+1][j]!='-' and positions[i][j+1]!='-' and positions[i-1][j]!='B'):
positions[i+1][j]='B'
positions[i][j+1]='B'
positions[i-1][j]='B'
elif i==n-1 and j==m-1:
if (positions[i-1][j]=='W' and positions[i][j-1]=='W') or (positions[i-1][j]=='-' and positions[i][j-1]=='W') or (positions[i-1][j]=='W' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i-1][j]=='B' and positions[i][j-1]!='-') or (positions[i-1][j]!='-' and positions[i][j-1]=='B'):
positions[i-1][j]='B'
positions[i][j-1]='B'
elif i==n-1:
if (positions[i][j+1]=='W' and positions[i][j-1]=='W' and positions[i-1][j]=='W') or (positions[i][j+1]=='-' and positions[i][j-1]=='W' and positions[i-1][j]=='W') or (positions[i][j+1]=='W' and positions[i][j-1]=='-' and positions[i-1][j]=='W') or (positions[i][j+1]=='W' and positions[i][j-1]=='W' and positions[i-1][j]=='-') or (positions[i][j+1]=='-' and positions[i][j-1]=='-' and positions[i-1][j]=='W') or (positions[i][j+1]=='-' and positions[i][j-1]=='W' and positions[i-1][j]=='-') or (positions[i][j+1]=='W' and positions[i][j-1]=='-' and positions[i-1][j]=='-'):
positions[i][j]='B'
elif (positions[i][j+1]=='B' and positions[i][j-1]!='-' and positions[i-1][j]!='-') or (positions[i][j+1]!='-' and positions[i][j-1]=='B' and positions[i-1][j]!='-') or (positions[i][j+1]!='-' and positions[i][j-1]!='-' and positions[i-1][j]=='B'):
positions[i][j+1]='B'
positions[i][j-1]='B'
positions[i-1][j]='B'
elif j==m-1:
if (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i-1][j]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]=='B' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]!='-' and positions[i][j-1]=='B'):
positions[i+1][j]='B'
positions[i-1][j]='B'
positions[i][j-1]='B'
else:
if (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='W') or (positions[i+1][j]=='-' and positions[i-1][j]=='-' and positions[i][j+1]=='W' and positions[i][j-1]=='-') or (positions[i+1][j]=='-' and positions[i-1][j]=='W' and positions[i][j+1]=='-' and positions[i][j-1]=='-') or (positions[i+1][j]=='W' and positions[i-1][j]=='-' and positions[i][j+1]=='-' and positions[i][j-1]=='-'):
positions[i][j]='B'
elif (positions[i+1][j]=='B' and positions[i-1][j]!='-' and positions[i][j+1]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]=='B' and positions[i][j+1]!='-' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]!='-' and positions[i][j+1]=='B' and positions[i][j-1]!='-') or (positions[i+1][j]!='-' and positions[i-1][j]!='-' and positions[i][j+1]!='-' and positions[i][j-1]=='B'):
positions[i+1][j]='B'
positions[i-1][j]='B'
positions[i][j+1]='B'
positions[i][j-1]='B'
n,m = input().split()
n,m = (int(n),int(m))
positions = [list(input()) for _ in range(n)]
fillgoodpositions(positions,n,m)
properpositioning(positions,n,m)
for i in range(n):
for j in range(m):
if j==m-1:
print(positions[i][j])
break
print(positions[i][j],end='')
```
| 0
|
|
255
|
D
|
Mr. Bender and Square
|
PROGRAMMING
| 1,800
|
[
"binary search",
"implementation",
"math"
] | null | null |
Mr. Bender has a digital table of size *n*<=×<=*n*, each cell can be switched on or off. He wants the field to have at least *c* switched on squares. When this condition is fulfilled, Mr Bender will be happy.
We'll consider the table rows numbered from top to bottom from 1 to *n*, and the columns — numbered from left to right from 1 to *n*. Initially there is exactly one switched on cell with coordinates (*x*,<=*y*) (*x* is the row number, *y* is the column number), and all other cells are switched off. Then each second we switch on the cells that are off but have the side-adjacent cells that are on.
For a cell with coordinates (*x*,<=*y*) the side-adjacent cells are cells with coordinates (*x*<=-<=1,<=*y*), (*x*<=+<=1,<=*y*), (*x*,<=*y*<=-<=1), (*x*,<=*y*<=+<=1).
In how many seconds will Mr. Bender get happy?
|
The first line contains four space-separated integers *n*,<=*x*,<=*y*,<=*c* (1<=≤<=*n*,<=*c*<=≤<=109; 1<=≤<=*x*,<=*y*<=≤<=*n*; *c*<=≤<=*n*2).
|
In a single line print a single integer — the answer to the problem.
|
[
"6 4 3 1\n",
"9 3 8 10\n"
] |
[
"0\n",
"2\n"
] |
Initially the first test has one painted cell, so the answer is 0. In the second test all events will go as is shown on the figure. <img class="tex-graphics" src="https://espresso.codeforces.com/51bd695513bdc59c6ded01f0d34daa5361285209.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
| 2,000
|
[
{
"input": "6 4 3 1",
"output": "0"
},
{
"input": "9 3 8 10",
"output": "2"
},
{
"input": "9 4 3 10",
"output": "2"
},
{
"input": "9 8 2 10",
"output": "2"
},
{
"input": "1 1 1 1",
"output": "0"
},
{
"input": "10 7 2 7",
"output": "2"
},
{
"input": "8 2 6 10",
"output": "2"
},
{
"input": "8 1 2 10",
"output": "3"
},
{
"input": "6 1 4 10",
"output": "3"
},
{
"input": "1000000 951981 612086 60277",
"output": "174"
},
{
"input": "1000000 587964 232616 62357",
"output": "177"
},
{
"input": "1000000 948438 69861 89178",
"output": "211"
},
{
"input": "1000000000 504951981 646612086 602763371",
"output": "17360"
},
{
"input": "1000000000 81587964 595232616 623563697",
"output": "17657"
},
{
"input": "1000000000 55 60 715189365",
"output": "37707"
},
{
"input": "1000000000 85 61 857945620",
"output": "41279"
},
{
"input": "1000000000 55 85 423654797",
"output": "28970"
},
{
"input": "1000000000 63 65 384381709",
"output": "27600"
},
{
"input": "1000000000 44 30 891773002",
"output": "42159"
},
{
"input": "1000000000 6 97 272656295",
"output": "23250"
},
{
"input": "1000000000 999999946 999999941 715189365",
"output": "37707"
},
{
"input": "1000000000 999999916 999999940 857945620",
"output": "41279"
},
{
"input": "1000000000 999999946 999999916 423654797",
"output": "28970"
},
{
"input": "1000000000 999999938 999999936 384381709",
"output": "27600"
},
{
"input": "1000000000 55 999999941 715189365",
"output": "37707"
},
{
"input": "1000000000 85 999999940 857945620",
"output": "41279"
},
{
"input": "1000000000 55 999999916 423654797",
"output": "28970"
},
{
"input": "1000000000 63 999999936 384381709",
"output": "27600"
},
{
"input": "1000000000 44 999999971 891773002",
"output": "42159"
},
{
"input": "1000000000 6 999999904 272656295",
"output": "23250"
},
{
"input": "1000000000 999999946 60 715189365",
"output": "37707"
},
{
"input": "1000000000 999999916 61 857945620",
"output": "41279"
},
{
"input": "1000000000 999999946 85 423654797",
"output": "28970"
},
{
"input": "1000000000 999999938 65 384381709",
"output": "27600"
},
{
"input": "1000000000 999999957 30 891773002",
"output": "42159"
},
{
"input": "548813503 532288332 26800940 350552333",
"output": "13239"
},
{
"input": "847251738 695702891 698306947 648440371",
"output": "18006"
},
{
"input": "891773002 152235342 682786380 386554406",
"output": "13902"
},
{
"input": "812168727 57791401 772019566 644719499",
"output": "17954"
},
{
"input": "71036059 25478942 38920202 19135721",
"output": "3093"
},
{
"input": "549 198 8 262611",
"output": "635"
},
{
"input": "848 409 661 620581",
"output": "771"
},
{
"input": "892 364 824 53858",
"output": "183"
},
{
"input": "813 154 643 141422",
"output": "299"
},
{
"input": "72 40 68 849",
"output": "25"
},
{
"input": "958 768 649 298927",
"output": "431"
},
{
"input": "800 305 317 414868",
"output": "489"
},
{
"input": "721 112 687 232556",
"output": "556"
},
{
"input": "522 228 495 74535",
"output": "249"
},
{
"input": "737 231 246 79279",
"output": "199"
},
{
"input": "6 4 3 36",
"output": "6"
},
{
"input": "9 3 8 55",
"output": "7"
},
{
"input": "9 4 3 73",
"output": "8"
},
{
"input": "9 8 2 50",
"output": "7"
},
{
"input": "1 1 1 1",
"output": "0"
},
{
"input": "10 7 2 7",
"output": "2"
},
{
"input": "8 2 6 20",
"output": "3"
},
{
"input": "8 1 2 64",
"output": "13"
},
{
"input": "6 1 4 15",
"output": "3"
},
{
"input": "8 8 3 1",
"output": "0"
}
] | 1,595,018,384
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 14
| 248
| 6,963,200
|
n, x, y, c = list(map(int, input().split()))
left, right = 0, 2 * n+1
while left < right:
mid = (left + right) // 2
temp = 2 * mid * (mid + 1) + 1
a = [x + mid - n, mid - y + 1, mid - x + 1, y + mid - n]
a = list(map(lambda x: max(0, x), a))
for e in a:
temp -= pow(e, 2)
for i in range(4):
temp += min(a[i], a[(i + 1) % 4]) * (min(a[i], a[(i + 1) % 4]) + 1) // 2
if temp >= c:
right = mid
else:
left = mid + 1
print((left + right) // 2)
|
Title: Mr. Bender and Square
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Mr. Bender has a digital table of size *n*<=×<=*n*, each cell can be switched on or off. He wants the field to have at least *c* switched on squares. When this condition is fulfilled, Mr Bender will be happy.
We'll consider the table rows numbered from top to bottom from 1 to *n*, and the columns — numbered from left to right from 1 to *n*. Initially there is exactly one switched on cell with coordinates (*x*,<=*y*) (*x* is the row number, *y* is the column number), and all other cells are switched off. Then each second we switch on the cells that are off but have the side-adjacent cells that are on.
For a cell with coordinates (*x*,<=*y*) the side-adjacent cells are cells with coordinates (*x*<=-<=1,<=*y*), (*x*<=+<=1,<=*y*), (*x*,<=*y*<=-<=1), (*x*,<=*y*<=+<=1).
In how many seconds will Mr. Bender get happy?
Input Specification:
The first line contains four space-separated integers *n*,<=*x*,<=*y*,<=*c* (1<=≤<=*n*,<=*c*<=≤<=109; 1<=≤<=*x*,<=*y*<=≤<=*n*; *c*<=≤<=*n*2).
Output Specification:
In a single line print a single integer — the answer to the problem.
Demo Input:
['6 4 3 1\n', '9 3 8 10\n']
Demo Output:
['0\n', '2\n']
Note:
Initially the first test has one painted cell, so the answer is 0. In the second test all events will go as is shown on the figure. <img class="tex-graphics" src="https://espresso.codeforces.com/51bd695513bdc59c6ded01f0d34daa5361285209.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
|
```python
n, x, y, c = list(map(int, input().split()))
left, right = 0, 2 * n+1
while left < right:
mid = (left + right) // 2
temp = 2 * mid * (mid + 1) + 1
a = [x + mid - n, mid - y + 1, mid - x + 1, y + mid - n]
a = list(map(lambda x: max(0, x), a))
for e in a:
temp -= pow(e, 2)
for i in range(4):
temp += min(a[i], a[(i + 1) % 4]) * (min(a[i], a[(i + 1) % 4]) + 1) // 2
if temp >= c:
right = mid
else:
left = mid + 1
print((left + right) // 2)
```
| 0
|
|
455
|
A
|
Boredom
|
PROGRAMMING
| 1,500
|
[
"dp"
] | null | null |
Alex doesn't like boredom. That's why whenever he gets bored, he comes up with games. One long winter evening he came up with a game and decided to play it.
Given a sequence *a* consisting of *n* integers. The player can make several steps. In a single step he can choose an element of the sequence (let's denote it *a**k*) and delete it, at that all elements equal to *a**k*<=+<=1 and *a**k*<=-<=1 also must be deleted from the sequence. That step brings *a**k* points to the player.
Alex is a perfectionist, so he decided to get as many points as possible. Help him.
|
The first line contains integer *n* (1<=≤<=*n*<=≤<=105) that shows how many numbers are in Alex's sequence.
The second line contains *n* integers *a*1, *a*2, ..., *a**n* (1<=≤<=*a**i*<=≤<=105).
|
Print a single integer — the maximum number of points that Alex can earn.
|
[
"2\n1 2\n",
"3\n1 2 3\n",
"9\n1 2 1 3 2 2 2 2 3\n"
] |
[
"2\n",
"4\n",
"10\n"
] |
Consider the third test example. At first step we need to choose any element equal to 2. After that step our sequence looks like this [2, 2, 2, 2]. Then we do 4 steps, on each step we choose any element equals to 2. In total we earn 10 points.
| 500
|
[
{
"input": "2\n1 2",
"output": "2"
},
{
"input": "3\n1 2 3",
"output": "4"
},
{
"input": "9\n1 2 1 3 2 2 2 2 3",
"output": "10"
},
{
"input": "5\n3 3 4 5 4",
"output": "11"
},
{
"input": "5\n5 3 5 3 4",
"output": "16"
},
{
"input": "5\n4 2 3 2 5",
"output": "9"
},
{
"input": "10\n10 5 8 9 5 6 8 7 2 8",
"output": "46"
},
{
"input": "10\n1 1 1 1 1 1 2 3 4 4",
"output": "14"
},
{
"input": "100\n6 6 8 9 7 9 6 9 5 7 7 4 5 3 9 1 10 3 4 5 8 9 6 5 6 4 10 9 1 4 1 7 1 4 9 10 8 2 9 9 10 5 8 9 5 6 8 7 2 8 7 6 2 6 10 8 6 2 5 5 3 2 8 8 5 3 6 2 1 4 7 2 7 3 7 4 10 10 7 5 4 7 5 10 7 1 1 10 7 7 7 2 3 4 2 8 4 7 4 4",
"output": "296"
},
{
"input": "100\n6 1 5 7 10 10 2 7 3 7 2 10 7 6 3 5 5 5 3 7 2 4 2 7 7 4 2 8 2 10 4 7 9 1 1 7 9 7 1 10 10 9 5 6 10 1 7 5 8 1 1 5 3 10 2 4 3 5 2 7 4 9 5 10 1 3 7 6 6 9 3 6 6 10 1 10 6 1 10 3 4 1 7 9 2 7 8 9 3 3 2 4 6 6 1 2 9 4 1 2",
"output": "313"
},
{
"input": "100\n7 6 3 8 8 3 10 5 3 8 6 4 6 9 6 7 3 9 10 7 5 5 9 10 7 2 3 8 9 5 4 7 9 3 6 4 9 10 7 6 8 7 6 6 10 3 7 4 5 7 7 5 1 5 4 8 7 3 3 4 7 8 5 9 2 2 3 1 6 4 6 6 6 1 7 10 7 4 5 3 9 2 4 1 5 10 9 3 9 6 8 5 2 1 10 4 8 5 10 9",
"output": "298"
},
{
"input": "100\n2 10 9 1 2 6 7 2 2 8 9 9 9 5 6 2 5 1 1 10 7 4 5 5 8 1 9 4 10 1 9 3 1 8 4 10 8 8 2 4 6 5 1 4 2 2 1 2 8 5 3 9 4 10 10 7 8 6 1 8 2 6 7 1 6 7 3 10 10 3 7 7 6 9 6 8 8 10 4 6 4 3 3 3 2 3 10 6 8 5 5 10 3 7 3 1 1 1 5 5",
"output": "312"
},
{
"input": "100\n4 9 7 10 4 7 2 6 1 9 1 8 7 5 5 7 6 7 9 8 10 5 3 5 7 10 3 2 1 3 8 9 4 10 4 7 6 4 9 6 7 1 9 4 3 5 8 9 2 7 10 5 7 5 3 8 10 3 8 9 3 4 3 10 6 5 1 8 3 2 5 8 4 7 5 3 3 2 6 9 9 8 2 7 6 3 2 2 8 8 4 5 6 9 2 3 2 2 5 2",
"output": "287"
},
{
"input": "100\n4 8 10 1 8 8 8 1 10 3 1 8 6 8 6 1 10 3 3 3 3 7 2 1 1 6 10 1 7 9 8 10 3 8 6 2 1 6 5 6 10 8 9 7 4 3 10 5 3 9 10 5 10 8 8 5 7 8 9 5 3 9 9 2 7 8 1 10 4 9 2 8 10 10 5 8 5 1 7 3 4 5 2 5 9 3 2 5 6 2 3 10 1 5 9 6 10 4 10 8",
"output": "380"
},
{
"input": "100\n4 8 10 1 8 8 8 1 10 3 1 8 6 8 6 1 10 3 3 3 3 7 2 1 1 6 10 1 7 9 8 10 3 8 6 2 1 6 5 6 10 8 9 7 4 3 10 5 3 9 10 5 10 8 8 5 7 8 9 5 3 9 9 2 7 8 1 10 4 9 2 8 10 10 5 8 5 1 7 3 4 5 2 5 9 3 2 5 6 2 3 10 1 5 9 6 10 4 10 8",
"output": "380"
},
{
"input": "100\n10 5 8 4 4 4 1 4 5 8 3 10 2 4 1 10 8 1 1 6 8 4 2 9 1 3 1 7 7 9 3 5 5 8 6 9 9 4 8 1 3 3 2 6 1 5 4 5 3 5 5 6 7 5 7 9 3 5 4 9 2 6 8 1 1 7 7 3 8 9 8 7 3 2 4 1 6 1 3 9 4 2 2 8 5 10 1 8 8 5 1 5 6 9 4 5 6 5 10 2",
"output": "265"
},
{
"input": "100\n7 5 1 8 5 6 6 2 6 2 7 7 3 6 2 4 4 2 10 2 2 2 10 6 6 1 5 10 9 1 5 9 8 9 4 1 10 5 7 5 7 6 4 8 8 1 7 8 3 8 2 1 8 4 10 3 5 6 6 10 9 6 5 1 10 7 6 9 9 2 10 10 9 1 2 1 7 7 4 10 1 10 5 5 3 8 9 8 1 4 10 2 4 5 4 4 1 6 2 9",
"output": "328"
},
{
"input": "100\n5 6 10 7 1 7 10 1 9 1 5 1 4 1 3 3 7 9 1 6 1 6 5 7 1 6 3 1 3 6 3 8 2 4 1 5 2 10 7 3 10 4 10 1 5 4 2 9 7 9 5 7 10 4 1 4 8 9 3 1 3 7 7 4 3 7 7 10 6 9 5 5 6 5 3 9 8 8 5 5 4 10 9 4 10 4 1 8 3 5 4 10 9 3 10 4 10 7 10 9",
"output": "324"
},
{
"input": "10\n7 4 5 3 9 1 10 3 4 5",
"output": "34"
},
{
"input": "10\n8 9 6 5 6 4 10 9 1 4",
"output": "39"
},
{
"input": "10\n1 7 1 4 9 10 8 2 9 9",
"output": "40"
},
{
"input": "1\n100000",
"output": "100000"
}
] | 1,668,680,187
| 2,147,483,647
|
PyPy 3-64
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 11
| 1,000
| 17,305,600
|
nums = int(input())
sequence = list(map(int,input().split()))
sequence.sort()
simple_sequence = []
counting = []
count = 0
for x in range(nums):
count = count + 1
if x == nums - 1 or sequence[x] != sequence[x+1] :
counting.append(count)
simple_sequence.append(sequence[x])
count = 0
bag = []
worth = [0] * (max(simple_sequence) + 2)
delete = 0
for q in range(len(simple_sequence)):
item = simple_sequence[q]
addition = item * counting[q]
for test in range(len(worth[item:])):
position = test + item
old_worth = worth[position]
new_worth = worth[item - 2] + addition
worth[position] = max(old_worth,new_worth)
print(max(worth))
|
Title: Boredom
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Alex doesn't like boredom. That's why whenever he gets bored, he comes up with games. One long winter evening he came up with a game and decided to play it.
Given a sequence *a* consisting of *n* integers. The player can make several steps. In a single step he can choose an element of the sequence (let's denote it *a**k*) and delete it, at that all elements equal to *a**k*<=+<=1 and *a**k*<=-<=1 also must be deleted from the sequence. That step brings *a**k* points to the player.
Alex is a perfectionist, so he decided to get as many points as possible. Help him.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=105) that shows how many numbers are in Alex's sequence.
The second line contains *n* integers *a*1, *a*2, ..., *a**n* (1<=≤<=*a**i*<=≤<=105).
Output Specification:
Print a single integer — the maximum number of points that Alex can earn.
Demo Input:
['2\n1 2\n', '3\n1 2 3\n', '9\n1 2 1 3 2 2 2 2 3\n']
Demo Output:
['2\n', '4\n', '10\n']
Note:
Consider the third test example. At first step we need to choose any element equal to 2. After that step our sequence looks like this [2, 2, 2, 2]. Then we do 4 steps, on each step we choose any element equals to 2. In total we earn 10 points.
|
```python
nums = int(input())
sequence = list(map(int,input().split()))
sequence.sort()
simple_sequence = []
counting = []
count = 0
for x in range(nums):
count = count + 1
if x == nums - 1 or sequence[x] != sequence[x+1] :
counting.append(count)
simple_sequence.append(sequence[x])
count = 0
bag = []
worth = [0] * (max(simple_sequence) + 2)
delete = 0
for q in range(len(simple_sequence)):
item = simple_sequence[q]
addition = item * counting[q]
for test in range(len(worth[item:])):
position = test + item
old_worth = worth[position]
new_worth = worth[item - 2] + addition
worth[position] = max(old_worth,new_worth)
print(max(worth))
```
| 0
|
|
50
|
A
|
Domino piling
|
PROGRAMMING
| 800
|
[
"greedy",
"math"
] |
A. Domino piling
|
2
|
256
|
You are given a rectangular board of *M*<=×<=*N* squares. Also you are given an unlimited number of standard domino pieces of 2<=×<=1 squares. You are allowed to rotate the pieces. You are asked to place as many dominoes as possible on the board so as to meet the following conditions:
1. Each domino completely covers two squares.
2. No two dominoes overlap.
3. Each domino lies entirely inside the board. It is allowed to touch the edges of the board.
Find the maximum number of dominoes, which can be placed under these restrictions.
|
In a single line you are given two integers *M* and *N* — board sizes in squares (1<=≤<=*M*<=≤<=*N*<=≤<=16).
|
Output one number — the maximal number of dominoes, which can be placed.
|
[
"2 4\n",
"3 3\n"
] |
[
"4\n",
"4\n"
] |
none
| 500
|
[
{
"input": "2 4",
"output": "4"
},
{
"input": "3 3",
"output": "4"
},
{
"input": "1 5",
"output": "2"
},
{
"input": "1 6",
"output": "3"
},
{
"input": "1 15",
"output": "7"
},
{
"input": "1 16",
"output": "8"
},
{
"input": "2 5",
"output": "5"
},
{
"input": "2 6",
"output": "6"
},
{
"input": "2 7",
"output": "7"
},
{
"input": "2 14",
"output": "14"
},
{
"input": "2 15",
"output": "15"
},
{
"input": "1 4",
"output": "2"
},
{
"input": "2 16",
"output": "16"
},
{
"input": "3 5",
"output": "7"
},
{
"input": "3 6",
"output": "9"
},
{
"input": "3 10",
"output": "15"
},
{
"input": "3 14",
"output": "21"
},
{
"input": "3 15",
"output": "22"
},
{
"input": "3 16",
"output": "24"
},
{
"input": "5 7",
"output": "17"
},
{
"input": "16 16",
"output": "128"
},
{
"input": "15 16",
"output": "120"
},
{
"input": "2 3",
"output": "3"
},
{
"input": "15 15",
"output": "112"
},
{
"input": "14 16",
"output": "112"
},
{
"input": "11 13",
"output": "71"
},
{
"input": "5 16",
"output": "40"
},
{
"input": "8 15",
"output": "60"
},
{
"input": "2 2",
"output": "2"
},
{
"input": "3 4",
"output": "6"
},
{
"input": "4 4",
"output": "8"
},
{
"input": "1 1",
"output": "0"
},
{
"input": "1 2",
"output": "1"
},
{
"input": "1 3",
"output": "1"
},
{
"input": "14 15",
"output": "105"
}
] | 1,633,962,390
| 2,147,483,647
|
Python 3
|
COMPILATION_ERROR
|
TESTS
| 0
| 0
| 0
|
n,m=map(int,raw_input().split())
num=(n/2)*m
if n%2==1:
num+=(m/2)
print num
|
Title: Domino piling
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
You are given a rectangular board of *M*<=×<=*N* squares. Also you are given an unlimited number of standard domino pieces of 2<=×<=1 squares. You are allowed to rotate the pieces. You are asked to place as many dominoes as possible on the board so as to meet the following conditions:
1. Each domino completely covers two squares.
2. No two dominoes overlap.
3. Each domino lies entirely inside the board. It is allowed to touch the edges of the board.
Find the maximum number of dominoes, which can be placed under these restrictions.
Input Specification:
In a single line you are given two integers *M* and *N* — board sizes in squares (1<=≤<=*M*<=≤<=*N*<=≤<=16).
Output Specification:
Output one number — the maximal number of dominoes, which can be placed.
Demo Input:
['2 4\n', '3 3\n']
Demo Output:
['4\n', '4\n']
Note:
none
|
```python
n,m=map(int,raw_input().split())
num=(n/2)*m
if n%2==1:
num+=(m/2)
print num
```
| -1
|
116
|
A
|
Tram
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Linear Kingdom has exactly one tram line. It has *n* stops, numbered from 1 to *n* in the order of tram's movement. At the *i*-th stop *a**i* passengers exit the tram, while *b**i* passengers enter it. The tram is empty before it arrives at the first stop. Also, when the tram arrives at the last stop, all passengers exit so that it becomes empty.
Your task is to calculate the tram's minimum capacity such that the number of people inside the tram at any time never exceeds this capacity. Note that at each stop all exiting passengers exit before any entering passenger enters the tram.
|
The first line contains a single number *n* (2<=≤<=*n*<=≤<=1000) — the number of the tram's stops.
Then *n* lines follow, each contains two integers *a**i* and *b**i* (0<=≤<=*a**i*,<=*b**i*<=≤<=1000) — the number of passengers that exits the tram at the *i*-th stop, and the number of passengers that enter the tram at the *i*-th stop. The stops are given from the first to the last stop in the order of tram's movement.
- The number of people who exit at a given stop does not exceed the total number of people in the tram immediately before it arrives at the stop. More formally, . This particularly means that *a*1<==<=0. - At the last stop, all the passengers exit the tram and it becomes empty. More formally, . - No passenger will enter the train at the last stop. That is, *b**n*<==<=0.
|
Print a single integer denoting the minimum possible capacity of the tram (0 is allowed).
|
[
"4\n0 3\n2 5\n4 2\n4 0\n"
] |
[
"6\n"
] |
For the first example, a capacity of 6 is sufficient:
- At the first stop, the number of passengers inside the tram before arriving is 0. Then, 3 passengers enter the tram, and the number of passengers inside the tram becomes 3. - At the second stop, 2 passengers exit the tram (1 passenger remains inside). Then, 5 passengers enter the tram. There are 6 passengers inside the tram now. - At the third stop, 4 passengers exit the tram (2 passengers remain inside). Then, 2 passengers enter the tram. There are 4 passengers inside the tram now. - Finally, all the remaining passengers inside the tram exit the tram at the last stop. There are no passenger inside the tram now, which is in line with the constraints.
Since the number of passengers inside the tram never exceeds 6, a capacity of 6 is sufficient. Furthermore it is not possible for the tram to have a capacity less than 6. Hence, 6 is the correct answer.
| 500
|
[
{
"input": "4\n0 3\n2 5\n4 2\n4 0",
"output": "6"
},
{
"input": "5\n0 4\n4 6\n6 5\n5 4\n4 0",
"output": "6"
},
{
"input": "10\n0 5\n1 7\n10 8\n5 3\n0 5\n3 3\n8 8\n0 6\n10 1\n9 0",
"output": "18"
},
{
"input": "3\n0 1\n1 1\n1 0",
"output": "1"
},
{
"input": "4\n0 1\n0 1\n1 0\n1 0",
"output": "2"
},
{
"input": "3\n0 0\n0 0\n0 0",
"output": "0"
},
{
"input": "3\n0 1000\n1000 1000\n1000 0",
"output": "1000"
},
{
"input": "5\n0 73\n73 189\n189 766\n766 0\n0 0",
"output": "766"
},
{
"input": "5\n0 0\n0 0\n0 0\n0 1\n1 0",
"output": "1"
},
{
"input": "5\n0 917\n917 923\n904 992\n1000 0\n11 0",
"output": "1011"
},
{
"input": "5\n0 1\n1 2\n2 1\n1 2\n2 0",
"output": "2"
},
{
"input": "5\n0 0\n0 0\n0 0\n0 0\n0 0",
"output": "0"
},
{
"input": "20\n0 7\n2 1\n2 2\n5 7\n2 6\n6 10\n2 4\n0 4\n7 4\n8 0\n10 6\n2 1\n6 1\n1 7\n0 3\n8 7\n6 3\n6 3\n1 1\n3 0",
"output": "22"
},
{
"input": "5\n0 1000\n1000 1000\n1000 1000\n1000 1000\n1000 0",
"output": "1000"
},
{
"input": "10\n0 592\n258 598\n389 203\n249 836\n196 635\n478 482\n994 987\n1000 0\n769 0\n0 0",
"output": "1776"
},
{
"input": "10\n0 1\n1 0\n0 0\n0 0\n0 0\n0 1\n1 1\n0 1\n1 0\n1 0",
"output": "2"
},
{
"input": "10\n0 926\n926 938\n938 931\n931 964\n937 989\n983 936\n908 949\n997 932\n945 988\n988 0",
"output": "1016"
},
{
"input": "10\n0 1\n1 2\n1 2\n2 2\n2 2\n2 2\n1 1\n1 1\n2 1\n2 0",
"output": "3"
},
{
"input": "10\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0",
"output": "0"
},
{
"input": "10\n0 1000\n1000 1000\n1000 1000\n1000 1000\n1000 1000\n1000 1000\n1000 1000\n1000 1000\n1000 1000\n1000 0",
"output": "1000"
},
{
"input": "50\n0 332\n332 268\n268 56\n56 711\n420 180\n160 834\n149 341\n373 777\n763 93\n994 407\n86 803\n700 132\n471 608\n429 467\n75 5\n638 305\n405 853\n316 478\n643 163\n18 131\n648 241\n241 766\n316 847\n640 380\n923 759\n789 41\n125 421\n421 9\n9 388\n388 829\n408 108\n462 856\n816 411\n518 688\n290 7\n405 912\n397 772\n396 652\n394 146\n27 648\n462 617\n514 433\n780 35\n710 705\n460 390\n194 508\n643 56\n172 469\n1000 0\n194 0",
"output": "2071"
},
{
"input": "50\n0 0\n0 1\n1 1\n0 1\n0 0\n1 0\n0 0\n1 0\n0 0\n0 0\n0 0\n0 0\n0 1\n0 0\n0 0\n0 1\n1 0\n0 1\n0 0\n1 1\n1 0\n0 1\n0 0\n1 1\n0 1\n1 0\n1 1\n1 0\n0 0\n1 1\n1 0\n0 1\n0 0\n0 1\n1 1\n1 1\n1 1\n1 0\n1 1\n1 0\n0 1\n1 0\n0 0\n0 1\n1 1\n1 1\n0 1\n0 0\n1 0\n1 0",
"output": "3"
},
{
"input": "50\n0 926\n926 971\n915 980\n920 965\n954 944\n928 952\n955 980\n916 980\n906 935\n944 913\n905 923\n912 922\n965 934\n912 900\n946 930\n931 983\n979 905\n925 969\n924 926\n910 914\n921 977\n934 979\n962 986\n942 909\n976 903\n982 982\n991 941\n954 929\n902 980\n947 983\n919 924\n917 943\n916 905\n907 913\n964 977\n984 904\n905 999\n950 970\n986 906\n993 970\n960 994\n963 983\n918 986\n980 900\n931 986\n993 997\n941 909\n907 909\n1000 0\n278 0",
"output": "1329"
},
{
"input": "2\n0 863\n863 0",
"output": "863"
},
{
"input": "50\n0 1\n1 2\n2 2\n1 1\n1 1\n1 2\n1 2\n1 1\n1 2\n1 1\n1 1\n1 2\n1 2\n1 1\n2 1\n2 2\n1 2\n2 2\n1 2\n2 1\n2 1\n2 2\n2 1\n1 2\n1 2\n2 1\n1 1\n2 2\n1 1\n2 1\n2 2\n2 1\n1 2\n2 2\n1 2\n1 1\n1 1\n2 1\n2 1\n2 2\n2 1\n2 1\n1 2\n1 2\n1 2\n1 2\n2 0\n2 0\n2 0\n0 0",
"output": "8"
},
{
"input": "50\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0",
"output": "0"
},
{
"input": "100\n0 1\n0 0\n0 0\n1 0\n0 0\n0 1\n0 1\n1 1\n0 0\n0 0\n1 1\n0 0\n1 1\n0 1\n1 1\n0 1\n1 1\n1 0\n1 0\n0 0\n1 0\n0 1\n1 0\n0 0\n0 0\n1 1\n1 1\n0 1\n0 0\n1 0\n1 1\n0 1\n1 0\n1 1\n0 1\n1 1\n1 0\n0 0\n0 0\n0 1\n0 0\n0 1\n1 1\n0 0\n1 1\n1 1\n0 0\n0 1\n1 0\n0 1\n0 0\n0 1\n0 1\n1 1\n1 1\n1 1\n0 0\n0 0\n1 1\n0 1\n0 1\n1 0\n0 0\n0 0\n1 1\n0 1\n0 1\n1 1\n1 1\n0 1\n1 1\n1 1\n0 0\n1 0\n0 1\n0 0\n0 0\n1 1\n1 1\n1 1\n1 1\n0 1\n1 0\n1 0\n1 0\n1 0\n1 0\n0 0\n1 0\n1 0\n0 0\n1 0\n0 0\n0 1\n1 0\n0 1\n1 0\n1 0\n1 0\n1 0",
"output": "11"
},
{
"input": "100\n0 2\n1 2\n2 1\n1 2\n1 2\n2 1\n2 2\n1 1\n1 1\n2 1\n1 2\n2 1\n1 2\n2 2\n2 2\n2 2\n1 2\n2 2\n2 1\n1 1\n1 1\n1 1\n2 2\n1 2\n2 2\n1 1\n1 1\n1 1\n1 1\n2 2\n1 2\n2 1\n1 1\n2 2\n1 1\n2 1\n1 1\n2 2\n2 1\n1 2\n1 1\n1 2\n2 1\n2 2\n1 1\n2 1\n1 1\n2 1\n1 1\n1 2\n2 2\n2 2\n1 1\n2 2\n1 2\n2 1\n2 1\n1 1\n1 1\n1 2\n1 2\n1 1\n1 1\n2 1\n1 2\n1 2\n2 1\n2 2\n2 2\n2 2\n2 1\n2 2\n1 1\n1 2\n1 2\n1 1\n2 2\n2 2\n1 1\n2 1\n1 1\n1 2\n1 2\n1 2\n1 1\n1 1\n2 2\n1 2\n2 1\n2 1\n2 1\n1 2\n1 2\n1 1\n2 2\n1 2\n2 0\n2 0\n2 0\n1 0",
"output": "7"
},
{
"input": "100\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0",
"output": "0"
},
{
"input": "2\n0 1\n1 0",
"output": "1"
},
{
"input": "2\n0 900\n900 0",
"output": "900"
},
{
"input": "2\n0 1\n1 0",
"output": "1"
},
{
"input": "2\n0 0\n0 0",
"output": "0"
},
{
"input": "2\n0 1000\n1000 0",
"output": "1000"
},
{
"input": "3\n0 802\n175 188\n815 0",
"output": "815"
},
{
"input": "3\n0 910\n910 976\n976 0",
"output": "976"
},
{
"input": "3\n0 2\n2 1\n1 0",
"output": "2"
}
] | 1,691,690,226
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 71
| 92
| 102,400
|
def Tram(list_of_passenger) :
passengers_inside = 0
max_capacity = 0
for stop in list_of_passenger:
passengers_inside -= stop[0] # Passengers exit
passengers_inside += stop[1] # Passengers enter
max_capacity = max(max_capacity, passengers_inside)
return max_capacity
if __name__ == "__main__":
list_of_passenger = list()
for i in range(int(input())):
outside , inside = map(int , input().split())
list_of_passenger.append([outside,inside])
print(Tram(list_of_passenger))
|
Title: Tram
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Linear Kingdom has exactly one tram line. It has *n* stops, numbered from 1 to *n* in the order of tram's movement. At the *i*-th stop *a**i* passengers exit the tram, while *b**i* passengers enter it. The tram is empty before it arrives at the first stop. Also, when the tram arrives at the last stop, all passengers exit so that it becomes empty.
Your task is to calculate the tram's minimum capacity such that the number of people inside the tram at any time never exceeds this capacity. Note that at each stop all exiting passengers exit before any entering passenger enters the tram.
Input Specification:
The first line contains a single number *n* (2<=≤<=*n*<=≤<=1000) — the number of the tram's stops.
Then *n* lines follow, each contains two integers *a**i* and *b**i* (0<=≤<=*a**i*,<=*b**i*<=≤<=1000) — the number of passengers that exits the tram at the *i*-th stop, and the number of passengers that enter the tram at the *i*-th stop. The stops are given from the first to the last stop in the order of tram's movement.
- The number of people who exit at a given stop does not exceed the total number of people in the tram immediately before it arrives at the stop. More formally, . This particularly means that *a*1<==<=0. - At the last stop, all the passengers exit the tram and it becomes empty. More formally, . - No passenger will enter the train at the last stop. That is, *b**n*<==<=0.
Output Specification:
Print a single integer denoting the minimum possible capacity of the tram (0 is allowed).
Demo Input:
['4\n0 3\n2 5\n4 2\n4 0\n']
Demo Output:
['6\n']
Note:
For the first example, a capacity of 6 is sufficient:
- At the first stop, the number of passengers inside the tram before arriving is 0. Then, 3 passengers enter the tram, and the number of passengers inside the tram becomes 3. - At the second stop, 2 passengers exit the tram (1 passenger remains inside). Then, 5 passengers enter the tram. There are 6 passengers inside the tram now. - At the third stop, 4 passengers exit the tram (2 passengers remain inside). Then, 2 passengers enter the tram. There are 4 passengers inside the tram now. - Finally, all the remaining passengers inside the tram exit the tram at the last stop. There are no passenger inside the tram now, which is in line with the constraints.
Since the number of passengers inside the tram never exceeds 6, a capacity of 6 is sufficient. Furthermore it is not possible for the tram to have a capacity less than 6. Hence, 6 is the correct answer.
|
```python
def Tram(list_of_passenger) :
passengers_inside = 0
max_capacity = 0
for stop in list_of_passenger:
passengers_inside -= stop[0] # Passengers exit
passengers_inside += stop[1] # Passengers enter
max_capacity = max(max_capacity, passengers_inside)
return max_capacity
if __name__ == "__main__":
list_of_passenger = list()
for i in range(int(input())):
outside , inside = map(int , input().split())
list_of_passenger.append([outside,inside])
print(Tram(list_of_passenger))
```
| 3
|
|
0
|
none
|
none
|
none
| 0
|
[
"none"
] | null | null |
Vlad likes to eat in cafes very much. During his life, he has visited cafes *n* times. Unfortunately, Vlad started to feel that his last visits are not any different from each other. To fix that Vlad had a small research.
First of all, Vlad assigned individual indices to all cafes. Then, he wrote down indices of cafes he visited in a row, in order of visiting them. Now, Vlad wants to find such a cafe that his last visit to that cafe was before his last visits to every other cafe. In other words, he wants to find such a cafe that he hasn't been there for as long as possible. Help Vlad to find that cafe.
|
In first line there is one integer *n* (1<=≤<=*n*<=≤<=2·105) — number of cafes indices written by Vlad.
In second line, *n* numbers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=≤<=2·105) are written — indices of cafes in order of being visited by Vlad. Vlad could visit some cafes more than once. Note that in numeration, some indices could be omitted.
|
Print one integer — index of the cafe that Vlad hasn't visited for as long as possible.
|
[
"5\n1 3 2 1 2\n",
"6\n2 1 2 2 4 1\n"
] |
[
"3\n",
"2\n"
] |
In first test, there are three cafes, and the last visits to cafes with indices 1 and 2 were after the last visit to cafe with index 3; so this cafe is the answer.
In second test case, there are also three cafes, but with indices 1, 2 and 4. Cafes with indices 1 and 4 were visited after the last visit of cafe with index 2, so the answer is 2. Note that Vlad could omit some numbers while numerating the cafes.
| 0
|
[
{
"input": "5\n1 3 2 1 2",
"output": "3"
},
{
"input": "6\n2 1 2 2 4 1",
"output": "2"
},
{
"input": "1\n0",
"output": "0"
},
{
"input": "1\n200000",
"output": "200000"
},
{
"input": "2\n2018 2017",
"output": "2018"
},
{
"input": "5\n100 1000 1000 1000 1000",
"output": "100"
},
{
"input": "8\n200000 1 200000 1 200000 1 200000 2",
"output": "1"
},
{
"input": "5\n20000 1 2 3 4",
"output": "20000"
},
{
"input": "2\n200000 1",
"output": "200000"
},
{
"input": "3\n2 100 2",
"output": "100"
},
{
"input": "2\n10 1",
"output": "10"
},
{
"input": "11\n1 1 1 1 1 1 1 1 1 1 1",
"output": "1"
},
{
"input": "3\n5 5 5",
"output": "5"
},
{
"input": "2\n5 1",
"output": "5"
}
] | 1,511,439,757
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 62
| 2,457,600
|
n = int(input())
a = input().split()
for i in range(len(a)):
a[i] = int(a[i])
b = list(set(a))
l = len(b)
dp = [False for i in range(200001)]
for i in a[::-1]:
if dp[i] == False:
dp[i] = True
l -= 1
if l == 1:
break
for i in b:
if dp[i] == False:
print(i)
|
Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vlad likes to eat in cafes very much. During his life, he has visited cafes *n* times. Unfortunately, Vlad started to feel that his last visits are not any different from each other. To fix that Vlad had a small research.
First of all, Vlad assigned individual indices to all cafes. Then, he wrote down indices of cafes he visited in a row, in order of visiting them. Now, Vlad wants to find such a cafe that his last visit to that cafe was before his last visits to every other cafe. In other words, he wants to find such a cafe that he hasn't been there for as long as possible. Help Vlad to find that cafe.
Input Specification:
In first line there is one integer *n* (1<=≤<=*n*<=≤<=2·105) — number of cafes indices written by Vlad.
In second line, *n* numbers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=≤<=2·105) are written — indices of cafes in order of being visited by Vlad. Vlad could visit some cafes more than once. Note that in numeration, some indices could be omitted.
Output Specification:
Print one integer — index of the cafe that Vlad hasn't visited for as long as possible.
Demo Input:
['5\n1 3 2 1 2\n', '6\n2 1 2 2 4 1\n']
Demo Output:
['3\n', '2\n']
Note:
In first test, there are three cafes, and the last visits to cafes with indices 1 and 2 were after the last visit to cafe with index 3; so this cafe is the answer.
In second test case, there are also three cafes, but with indices 1, 2 and 4. Cafes with indices 1 and 4 were visited after the last visit of cafe with index 2, so the answer is 2. Note that Vlad could omit some numbers while numerating the cafes.
|
```python
n = int(input())
a = input().split()
for i in range(len(a)):
a[i] = int(a[i])
b = list(set(a))
l = len(b)
dp = [False for i in range(200001)]
for i in a[::-1]:
if dp[i] == False:
dp[i] = True
l -= 1
if l == 1:
break
for i in b:
if dp[i] == False:
print(i)
```
| 0
|
|
719
|
A
|
Vitya in the Countryside
|
PROGRAMMING
| 1,100
|
[
"implementation"
] | null | null |
Every summer Vitya comes to visit his grandmother in the countryside. This summer, he got a huge wart. Every grandma knows that one should treat warts when the moon goes down. Thus, Vitya has to catch the moment when the moon is down.
Moon cycle lasts 30 days. The size of the visible part of the moon (in Vitya's units) for each day is 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, and then cycle repeats, thus after the second 1 again goes 0.
As there is no internet in the countryside, Vitya has been watching the moon for *n* consecutive days and for each of these days he wrote down the size of the visible part of the moon. Help him find out whether the moon will be up or down next day, or this cannot be determined by the data he has.
|
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=92) — the number of consecutive days Vitya was watching the size of the visible part of the moon.
The second line contains *n* integers *a**i* (0<=≤<=*a**i*<=≤<=15) — Vitya's records.
It's guaranteed that the input data is consistent.
|
If Vitya can be sure that the size of visible part of the moon on day *n*<=+<=1 will be less than the size of the visible part on day *n*, then print "DOWN" at the only line of the output. If he might be sure that the size of the visible part will increase, then print "UP". If it's impossible to determine what exactly will happen with the moon, print -1.
|
[
"5\n3 4 5 6 7\n",
"7\n12 13 14 15 14 13 12\n",
"1\n8\n"
] |
[
"UP\n",
"DOWN\n",
"-1\n"
] |
In the first sample, the size of the moon on the next day will be equal to 8, thus the answer is "UP".
In the second sample, the size of the moon on the next day will be 11, thus the answer is "DOWN".
In the third sample, there is no way to determine whether the size of the moon on the next day will be 7 or 9, thus the answer is -1.
| 500
|
[
{
"input": "5\n3 4 5 6 7",
"output": "UP"
},
{
"input": "7\n12 13 14 15 14 13 12",
"output": "DOWN"
},
{
"input": "1\n8",
"output": "-1"
},
{
"input": "44\n7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10",
"output": "DOWN"
},
{
"input": "92\n3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4",
"output": "UP"
},
{
"input": "6\n10 11 12 13 14 15",
"output": "DOWN"
},
{
"input": "27\n11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15",
"output": "DOWN"
},
{
"input": "6\n8 7 6 5 4 3",
"output": "DOWN"
},
{
"input": "27\n14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10",
"output": "UP"
},
{
"input": "79\n7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5",
"output": "DOWN"
},
{
"input": "25\n1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7",
"output": "DOWN"
},
{
"input": "21\n3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7",
"output": "DOWN"
},
{
"input": "56\n1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6",
"output": "DOWN"
},
{
"input": "19\n4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14",
"output": "UP"
},
{
"input": "79\n5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13",
"output": "UP"
},
{
"input": "87\n14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10",
"output": "UP"
},
{
"input": "13\n10 9 8 7 6 5 4 3 2 1 0 1 2",
"output": "UP"
},
{
"input": "2\n8 9",
"output": "UP"
},
{
"input": "3\n10 11 12",
"output": "UP"
},
{
"input": "1\n1",
"output": "-1"
},
{
"input": "1\n2",
"output": "-1"
},
{
"input": "1\n3",
"output": "-1"
},
{
"input": "1\n4",
"output": "-1"
},
{
"input": "1\n5",
"output": "-1"
},
{
"input": "1\n6",
"output": "-1"
},
{
"input": "1\n7",
"output": "-1"
},
{
"input": "1\n9",
"output": "-1"
},
{
"input": "1\n10",
"output": "-1"
},
{
"input": "1\n11",
"output": "-1"
},
{
"input": "1\n12",
"output": "-1"
},
{
"input": "1\n13",
"output": "-1"
},
{
"input": "1\n14",
"output": "-1"
},
{
"input": "1\n15",
"output": "DOWN"
},
{
"input": "1\n0",
"output": "UP"
},
{
"input": "3\n11 12 13",
"output": "UP"
},
{
"input": "2\n10 9",
"output": "DOWN"
},
{
"input": "92\n10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11",
"output": "UP"
},
{
"input": "92\n7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6",
"output": "DOWN"
},
{
"input": "2\n14 15",
"output": "DOWN"
},
{
"input": "2\n1 0",
"output": "UP"
},
{
"input": "2\n15 14",
"output": "DOWN"
},
{
"input": "92\n7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8",
"output": "UP"
},
{
"input": "92\n13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12",
"output": "DOWN"
},
{
"input": "92\n4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3",
"output": "DOWN"
},
{
"input": "92\n14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15",
"output": "DOWN"
},
{
"input": "92\n1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0",
"output": "UP"
},
{
"input": "2\n2 1",
"output": "DOWN"
},
{
"input": "3\n2 1 0",
"output": "UP"
},
{
"input": "5\n4 3 2 1 0",
"output": "UP"
},
{
"input": "2\n5 4",
"output": "DOWN"
},
{
"input": "4\n3 2 1 0",
"output": "UP"
},
{
"input": "3\n13 12 11",
"output": "DOWN"
},
{
"input": "2\n1 2",
"output": "UP"
},
{
"input": "2\n0 1",
"output": "UP"
},
{
"input": "2\n13 14",
"output": "UP"
},
{
"input": "14\n13 12 11 10 9 8 7 6 5 4 3 2 1 0",
"output": "UP"
}
] | 1,576,939,732
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 32
| 109
| 0
|
n = int(input())
s = list(map(int,input().split()))
if(len(s)==1) :
print(-1)
else :
if(s[-1]==15) :
print('DOWN')
else :
if(s[-1]-s[-2]>0) :
print('UP')
else :
print('DOWN')
|
Title: Vitya in the Countryside
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Every summer Vitya comes to visit his grandmother in the countryside. This summer, he got a huge wart. Every grandma knows that one should treat warts when the moon goes down. Thus, Vitya has to catch the moment when the moon is down.
Moon cycle lasts 30 days. The size of the visible part of the moon (in Vitya's units) for each day is 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, and then cycle repeats, thus after the second 1 again goes 0.
As there is no internet in the countryside, Vitya has been watching the moon for *n* consecutive days and for each of these days he wrote down the size of the visible part of the moon. Help him find out whether the moon will be up or down next day, or this cannot be determined by the data he has.
Input Specification:
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=92) — the number of consecutive days Vitya was watching the size of the visible part of the moon.
The second line contains *n* integers *a**i* (0<=≤<=*a**i*<=≤<=15) — Vitya's records.
It's guaranteed that the input data is consistent.
Output Specification:
If Vitya can be sure that the size of visible part of the moon on day *n*<=+<=1 will be less than the size of the visible part on day *n*, then print "DOWN" at the only line of the output. If he might be sure that the size of the visible part will increase, then print "UP". If it's impossible to determine what exactly will happen with the moon, print -1.
Demo Input:
['5\n3 4 5 6 7\n', '7\n12 13 14 15 14 13 12\n', '1\n8\n']
Demo Output:
['UP\n', 'DOWN\n', '-1\n']
Note:
In the first sample, the size of the moon on the next day will be equal to 8, thus the answer is "UP".
In the second sample, the size of the moon on the next day will be 11, thus the answer is "DOWN".
In the third sample, there is no way to determine whether the size of the moon on the next day will be 7 or 9, thus the answer is -1.
|
```python
n = int(input())
s = list(map(int,input().split()))
if(len(s)==1) :
print(-1)
else :
if(s[-1]==15) :
print('DOWN')
else :
if(s[-1]-s[-2]>0) :
print('UP')
else :
print('DOWN')
```
| 0
|
|
988
|
A
|
Diverse Team
|
PROGRAMMING
| 800
|
[
"brute force",
"implementation"
] | null | null |
There are $n$ students in a school class, the rating of the $i$-th student on Codehorses is $a_i$. You have to form a team consisting of $k$ students ($1 \le k \le n$) such that the ratings of all team members are distinct.
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct numbers which should be the indices of students in the team you form. If there are multiple answers, print any of them.
|
The first line contains two integers $n$ and $k$ ($1 \le k \le n \le 100$) — the number of students and the size of the team you have to form.
The second line contains $n$ integers $a_1, a_2, \dots, a_n$ ($1 \le a_i \le 100$), where $a_i$ is the rating of $i$-th student.
|
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct integers from $1$ to $n$ which should be the indices of students in the team you form. All the ratings of the students in the team should be distinct. You may print the indices in any order. If there are multiple answers, print any of them.
Assume that the students are numbered from $1$ to $n$.
|
[
"5 3\n15 13 15 15 12\n",
"5 4\n15 13 15 15 12\n",
"4 4\n20 10 40 30\n"
] |
[
"YES\n1 2 5 \n",
"NO\n",
"YES\n1 2 3 4 \n"
] |
All possible answers for the first example:
- {1 2 5} - {2 3 5} - {2 4 5}
Note that the order does not matter.
| 0
|
[
{
"input": "5 3\n15 13 15 15 12",
"output": "YES\n1 2 5 "
},
{
"input": "5 4\n15 13 15 15 12",
"output": "NO"
},
{
"input": "4 4\n20 10 40 30",
"output": "YES\n1 2 3 4 "
},
{
"input": "1 1\n1",
"output": "YES\n1 "
},
{
"input": "100 53\n16 17 1 2 27 5 9 9 53 24 17 33 35 24 20 48 56 73 12 14 39 55 58 13 59 73 29 26 40 33 22 29 34 22 55 38 63 66 36 13 60 42 10 15 21 9 11 5 23 37 79 47 26 3 79 53 44 8 71 75 42 11 34 39 79 33 10 26 23 23 17 14 54 41 60 31 83 5 45 4 14 35 6 60 28 48 23 18 60 36 21 28 7 34 9 25 52 43 54 19",
"output": "YES\n1 2 3 4 5 6 7 9 10 12 13 15 16 17 18 19 20 21 22 23 24 25 27 28 29 31 33 36 37 38 39 41 42 43 44 45 47 49 50 51 52 54 57 58 59 60 73 74 76 77 79 80 83 "
},
{
"input": "2 2\n100 100",
"output": "NO"
},
{
"input": "2 2\n100 99",
"output": "YES\n1 2 "
},
{
"input": "100 100\n63 100 75 32 53 24 73 98 76 15 70 48 8 81 88 58 95 78 27 92 14 16 72 43 46 39 66 38 64 42 59 9 22 51 4 6 10 94 28 99 68 80 35 50 45 20 47 7 30 26 49 91 77 19 96 57 65 1 11 13 31 12 82 87 93 34 62 3 21 79 56 41 89 18 44 23 74 86 2 33 69 36 61 67 25 83 5 84 90 37 40 29 97 60 52 55 54 71 17 85",
"output": "YES\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 "
},
{
"input": "100 41\n54 16 42 3 45 6 9 72 100 13 24 57 35 5 89 13 97 27 43 9 73 89 48 16 48 55 18 15 55 28 30 6 18 41 100 61 9 42 35 54 57 25 73 15 42 54 49 5 72 48 30 55 4 43 94 5 60 92 93 23 89 75 53 92 74 93 89 28 69 6 3 49 15 28 49 57 54 55 30 57 69 18 89 6 25 23 93 74 30 13 87 53 6 42 4 54 60 30 4 35",
"output": "NO"
},
{
"input": "100 2\n70 64 70 32 70 64 32 70 64 32 32 64 70 64 64 32 64 64 64 70 70 64 64 64 64 70 32 64 70 64 32 70 70 70 64 70 64 70 64 32 70 32 70 64 64 64 32 70 64 70 70 32 70 32 32 32 70 32 70 32 64 64 70 32 32 64 70 64 32 32 64 64 32 32 70 70 32 70 32 64 32 70 64 64 32 64 32 64 70 32 70 32 70 64 64 64 70 70 64 70",
"output": "YES\n1 2 "
}
] | 1,626,165,036
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 0
| 92
| 20,172,800
|
n, k = map(int, input().split(" "))
Ranks = list(map(int, input().split(" ")))
distincRanks = list(set(Ranks))
if len(distincRanks) < k:
print("NO")
else:
print("YES")
for i in range(k):
print(Ranks.index(distincRanks[i])+1, end= "")
|
Title: Diverse Team
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There are $n$ students in a school class, the rating of the $i$-th student on Codehorses is $a_i$. You have to form a team consisting of $k$ students ($1 \le k \le n$) such that the ratings of all team members are distinct.
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct numbers which should be the indices of students in the team you form. If there are multiple answers, print any of them.
Input Specification:
The first line contains two integers $n$ and $k$ ($1 \le k \le n \le 100$) — the number of students and the size of the team you have to form.
The second line contains $n$ integers $a_1, a_2, \dots, a_n$ ($1 \le a_i \le 100$), where $a_i$ is the rating of $i$-th student.
Output Specification:
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct integers from $1$ to $n$ which should be the indices of students in the team you form. All the ratings of the students in the team should be distinct. You may print the indices in any order. If there are multiple answers, print any of them.
Assume that the students are numbered from $1$ to $n$.
Demo Input:
['5 3\n15 13 15 15 12\n', '5 4\n15 13 15 15 12\n', '4 4\n20 10 40 30\n']
Demo Output:
['YES\n1 2 5 \n', 'NO\n', 'YES\n1 2 3 4 \n']
Note:
All possible answers for the first example:
- {1 2 5} - {2 3 5} - {2 4 5}
Note that the order does not matter.
|
```python
n, k = map(int, input().split(" "))
Ranks = list(map(int, input().split(" ")))
distincRanks = list(set(Ranks))
if len(distincRanks) < k:
print("NO")
else:
print("YES")
for i in range(k):
print(Ranks.index(distincRanks[i])+1, end= "")
```
| 0
|
|
279
|
B
|
Books
|
PROGRAMMING
| 1,400
|
[
"binary search",
"brute force",
"implementation",
"two pointers"
] | null | null |
When Valera has got some free time, he goes to the library to read some books. Today he's got *t* free minutes to read. That's why Valera took *n* books in the library and for each book he estimated the time he is going to need to read it. Let's number the books by integers from 1 to *n*. Valera needs *a**i* minutes to read the *i*-th book.
Valera decided to choose an arbitrary book with number *i* and read the books one by one, starting from this book. In other words, he will first read book number *i*, then book number *i*<=+<=1, then book number *i*<=+<=2 and so on. He continues the process until he either runs out of the free time or finishes reading the *n*-th book. Valera reads each book up to the end, that is, he doesn't start reading the book if he doesn't have enough free time to finish reading it.
Print the maximum number of books Valera can read.
|
The first line contains two integers *n* and *t* (1<=≤<=*n*<=≤<=105; 1<=≤<=*t*<=≤<=109) — the number of books and the number of free minutes Valera's got. The second line contains a sequence of *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=104), where number *a**i* shows the number of minutes that the boy needs to read the *i*-th book.
|
Print a single integer — the maximum number of books Valera can read.
|
[
"4 5\n3 1 2 1\n",
"3 3\n2 2 3\n"
] |
[
"3\n",
"1\n"
] |
none
| 1,000
|
[
{
"input": "4 5\n3 1 2 1",
"output": "3"
},
{
"input": "3 3\n2 2 3",
"output": "1"
},
{
"input": "1 3\n5",
"output": "0"
},
{
"input": "1 10\n4",
"output": "1"
},
{
"input": "2 10\n6 4",
"output": "2"
},
{
"input": "6 10\n2 3 4 2 1 1",
"output": "4"
},
{
"input": "7 13\n6 8 14 9 4 11 10",
"output": "2"
},
{
"input": "10 15\n10 9 1 1 5 10 5 3 7 2",
"output": "3"
},
{
"input": "20 30\n8 1 2 6 9 4 1 9 9 10 4 7 8 9 5 7 1 8 7 4",
"output": "6"
},
{
"input": "30 60\n16 13 22 38 13 35 17 17 20 38 12 19 9 22 20 3 35 34 34 21 35 40 22 3 27 19 12 4 8 19",
"output": "4"
},
{
"input": "100 100\n75 92 18 6 81 67 7 92 100 65 82 32 50 67 85 31 80 91 84 63 39 52 92 81 1 98 24 12 43 48 17 86 51 72 48 95 45 50 12 66 19 79 49 89 34 1 97 75 20 33 96 27 42 23 73 71 93 1 85 19 66 14 17 61 20 39 36 33 42 61 56 64 23 91 80 99 40 74 13 18 98 85 74 39 62 84 46 74 50 23 38 11 79 14 9 25 66 100 25 52",
"output": "3"
},
{
"input": "10 1\n4418 7528 8170 1736 1317 3205 8183 4995 8039 4708",
"output": "0"
},
{
"input": "50 2\n124 214 63 73 996 760 38 571 451 300 970 1 706 937 837 494 619 88 851 411 957 990 842 613 821 649 627 34 693 678 734 116 816 985 705 940 499 493 922 967 854 439 112 644 961 438 189 572 655 550",
"output": "1"
}
] | 1,674,058,064
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 7
| 62
| 0
|
def max_books(reading_time, t, books = 0):
for i in range(len(reading_time)):
if t - reading_time[i] >= 0:
books += 1
t -= reading_time[i]
return books
if __name__ == "__main__":
n,t = map(int,input().split())
reading_time = [int(x) for x in input().split()]
print (max_books(reading_time,t))
|
Title: Books
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
When Valera has got some free time, he goes to the library to read some books. Today he's got *t* free minutes to read. That's why Valera took *n* books in the library and for each book he estimated the time he is going to need to read it. Let's number the books by integers from 1 to *n*. Valera needs *a**i* minutes to read the *i*-th book.
Valera decided to choose an arbitrary book with number *i* and read the books one by one, starting from this book. In other words, he will first read book number *i*, then book number *i*<=+<=1, then book number *i*<=+<=2 and so on. He continues the process until he either runs out of the free time or finishes reading the *n*-th book. Valera reads each book up to the end, that is, he doesn't start reading the book if he doesn't have enough free time to finish reading it.
Print the maximum number of books Valera can read.
Input Specification:
The first line contains two integers *n* and *t* (1<=≤<=*n*<=≤<=105; 1<=≤<=*t*<=≤<=109) — the number of books and the number of free minutes Valera's got. The second line contains a sequence of *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=104), where number *a**i* shows the number of minutes that the boy needs to read the *i*-th book.
Output Specification:
Print a single integer — the maximum number of books Valera can read.
Demo Input:
['4 5\n3 1 2 1\n', '3 3\n2 2 3\n']
Demo Output:
['3\n', '1\n']
Note:
none
|
```python
def max_books(reading_time, t, books = 0):
for i in range(len(reading_time)):
if t - reading_time[i] >= 0:
books += 1
t -= reading_time[i]
return books
if __name__ == "__main__":
n,t = map(int,input().split())
reading_time = [int(x) for x in input().split()]
print (max_books(reading_time,t))
```
| 0
|
|
557
|
A
|
Ilya and Diplomas
|
PROGRAMMING
| 1,100
|
[
"greedy",
"implementation",
"math"
] | null | null |
Soon a school Olympiad in Informatics will be held in Berland, *n* schoolchildren will participate there.
At a meeting of the jury of the Olympiad it was decided that each of the *n* participants, depending on the results, will get a diploma of the first, second or third degree. Thus, each student will receive exactly one diploma.
They also decided that there must be given at least *min*1 and at most *max*1 diplomas of the first degree, at least *min*2 and at most *max*2 diplomas of the second degree, and at least *min*3 and at most *max*3 diplomas of the third degree.
After some discussion it was decided to choose from all the options of distributing diplomas satisfying these limitations the one that maximizes the number of participants who receive diplomas of the first degree. Of all these options they select the one which maximizes the number of the participants who receive diplomas of the second degree. If there are multiple of these options, they select the option that maximizes the number of diplomas of the third degree.
Choosing the best option of distributing certificates was entrusted to Ilya, one of the best programmers of Berland. However, he found more important things to do, so it is your task now to choose the best option of distributing of diplomas, based on the described limitations.
It is guaranteed that the described limitations are such that there is a way to choose such an option of distributing diplomas that all *n* participants of the Olympiad will receive a diploma of some degree.
|
The first line of the input contains a single integer *n* (3<=≤<=*n*<=≤<=3·106) — the number of schoolchildren who will participate in the Olympiad.
The next line of the input contains two integers *min*1 and *max*1 (1<=≤<=*min*1<=≤<=*max*1<=≤<=106) — the minimum and maximum limits on the number of diplomas of the first degree that can be distributed.
The third line of the input contains two integers *min*2 and *max*2 (1<=≤<=*min*2<=≤<=*max*2<=≤<=106) — the minimum and maximum limits on the number of diplomas of the second degree that can be distributed.
The next line of the input contains two integers *min*3 and *max*3 (1<=≤<=*min*3<=≤<=*max*3<=≤<=106) — the minimum and maximum limits on the number of diplomas of the third degree that can be distributed.
It is guaranteed that *min*1<=+<=*min*2<=+<=*min*3<=≤<=*n*<=≤<=*max*1<=+<=*max*2<=+<=*max*3.
|
In the first line of the output print three numbers, showing how many diplomas of the first, second and third degree will be given to students in the optimal variant of distributing diplomas.
The optimal variant of distributing diplomas is the one that maximizes the number of students who receive diplomas of the first degree. Of all the suitable options, the best one is the one which maximizes the number of participants who receive diplomas of the second degree. If there are several of these options, the best one is the one that maximizes the number of diplomas of the third degree.
|
[
"6\n1 5\n2 6\n3 7\n",
"10\n1 2\n1 3\n1 5\n",
"6\n1 3\n2 2\n2 2\n"
] |
[
"1 2 3 \n",
"2 3 5 \n",
"2 2 2 \n"
] |
none
| 500
|
[
{
"input": "6\n1 5\n2 6\n3 7",
"output": "1 2 3 "
},
{
"input": "10\n1 2\n1 3\n1 5",
"output": "2 3 5 "
},
{
"input": "6\n1 3\n2 2\n2 2",
"output": "2 2 2 "
},
{
"input": "55\n1 1000000\n40 50\n10 200",
"output": "5 40 10 "
},
{
"input": "3\n1 1\n1 1\n1 1",
"output": "1 1 1 "
},
{
"input": "3\n1 1000000\n1 1000000\n1 1000000",
"output": "1 1 1 "
},
{
"input": "1000\n100 400\n300 500\n400 1200",
"output": "300 300 400 "
},
{
"input": "3000000\n1 1000000\n1 1000000\n1 1000000",
"output": "1000000 1000000 1000000 "
},
{
"input": "11\n3 5\n3 5\n3 5",
"output": "5 3 3 "
},
{
"input": "12\n3 5\n3 5\n3 5",
"output": "5 4 3 "
},
{
"input": "13\n3 5\n3 5\n3 5",
"output": "5 5 3 "
},
{
"input": "3000000\n1000000 1000000\n1000000 1000000\n1000000 1000000",
"output": "1000000 1000000 1000000 "
},
{
"input": "50\n1 100\n1 100\n1 100",
"output": "48 1 1 "
},
{
"input": "1279\n123 670\n237 614\n846 923",
"output": "196 237 846 "
},
{
"input": "1589\n213 861\n5 96\n506 634",
"output": "861 96 632 "
},
{
"input": "2115\n987 987\n112 483\n437 959",
"output": "987 483 645 "
},
{
"input": "641\n251 960\n34 370\n149 149",
"output": "458 34 149 "
},
{
"input": "1655\n539 539\n10 425\n605 895",
"output": "539 425 691 "
},
{
"input": "1477\n210 336\n410 837\n448 878",
"output": "336 693 448 "
},
{
"input": "1707\n149 914\n190 422\n898 899",
"output": "619 190 898 "
},
{
"input": "1529\n515 515\n563 869\n169 451",
"output": "515 845 169 "
},
{
"input": "1543\n361 994\n305 407\n102 197",
"output": "994 407 142 "
},
{
"input": "1107\n471 849\n360 741\n71 473",
"output": "676 360 71 "
},
{
"input": "1629279\n267360 999930\n183077 674527\n202618 786988",
"output": "999930 426731 202618 "
},
{
"input": "1233589\n2850 555444\n500608 921442\n208610 607343",
"output": "524371 500608 208610 "
},
{
"input": "679115\n112687 183628\n101770 982823\n81226 781340",
"output": "183628 414261 81226 "
},
{
"input": "1124641\n117999 854291\n770798 868290\n76651 831405",
"output": "277192 770798 76651 "
},
{
"input": "761655\n88152 620061\n60403 688549\n79370 125321",
"output": "620061 62224 79370 "
},
{
"input": "2174477\n276494 476134\n555283 954809\n319941 935631",
"output": "476134 954809 743534 "
},
{
"input": "1652707\n201202 990776\n34796 883866\n162979 983308",
"output": "990776 498952 162979 "
},
{
"input": "2065529\n43217 891429\n434379 952871\n650231 855105",
"output": "891429 523869 650231 "
},
{
"input": "1702543\n405042 832833\n50931 747750\n381818 796831",
"output": "832833 487892 381818 "
},
{
"input": "501107\n19061 859924\n126478 724552\n224611 489718",
"output": "150018 126478 224611 "
},
{
"input": "1629279\n850831 967352\n78593 463906\n452094 885430",
"output": "967352 209833 452094 "
},
{
"input": "1233589\n2850 157021\n535109 748096\n392212 475634",
"output": "157021 684356 392212 "
},
{
"input": "679115\n125987 786267\n70261 688983\n178133 976789",
"output": "430721 70261 178133 "
},
{
"input": "1124641\n119407 734250\n213706 860770\n102149 102149",
"output": "734250 288242 102149 "
},
{
"input": "761655\n325539 325539\n280794 792505\n18540 106895",
"output": "325539 417576 18540 "
},
{
"input": "2174477\n352351 791072\n365110 969163\n887448 955610",
"output": "791072 495957 887448 "
},
{
"input": "1652707\n266774 638522\n65688 235422\n924898 992826",
"output": "638522 89287 924898 "
},
{
"input": "2065529\n608515 608515\n751563 864337\n614898 705451",
"output": "608515 842116 614898 "
},
{
"input": "1702543\n5784 996578\n47395 300407\n151614 710197",
"output": "996578 300407 405558 "
},
{
"input": "501107\n8073 390048\n190494 647328\n274071 376923",
"output": "36542 190494 274071 "
},
{
"input": "200\n50 50\n100 100\n50 50",
"output": "50 100 50 "
},
{
"input": "14\n1 100\n1 100\n8 9",
"output": "5 1 8 "
},
{
"input": "300\n200 400\n50 100\n40 80",
"output": "210 50 40 "
},
{
"input": "10\n3 6\n3 6\n3 6",
"output": "4 3 3 "
},
{
"input": "14\n3 6\n3 6\n3 6",
"output": "6 5 3 "
},
{
"input": "17\n3 6\n3 6\n3 6",
"output": "6 6 5 "
},
{
"input": "1000000\n300000 600000\n300000 600000\n300000 600000",
"output": "400000 300000 300000 "
},
{
"input": "1400000\n300000 600000\n300000 600000\n300000 600000",
"output": "600000 500000 300000 "
},
{
"input": "1700000\n300000 600000\n300000 600000\n300000 600000",
"output": "600000 600000 500000 "
},
{
"input": "561\n400 400\n80 80\n81 81",
"output": "400 80 81 "
},
{
"input": "2000\n100 1000\n1 1\n1 2000",
"output": "1000 1 999 "
},
{
"input": "1000002\n1 1000000\n1 1000000\n999999 1000000",
"output": "2 1 999999 "
},
{
"input": "1000002\n1 1000000\n1 1000000\n1000000 1000000",
"output": "1 1 1000000 "
}
] | 1,679,068,283
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 56
| 93
| 0
|
I=lambda:map(int,input().split())
n=next(I())
a,b=I()
c,d=I()
f,e=I()
x=min(b,n-c-f)
y=min(d,n-x-f)
print(x,y,n-x-y)
|
Title: Ilya and Diplomas
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Soon a school Olympiad in Informatics will be held in Berland, *n* schoolchildren will participate there.
At a meeting of the jury of the Olympiad it was decided that each of the *n* participants, depending on the results, will get a diploma of the first, second or third degree. Thus, each student will receive exactly one diploma.
They also decided that there must be given at least *min*1 and at most *max*1 diplomas of the first degree, at least *min*2 and at most *max*2 diplomas of the second degree, and at least *min*3 and at most *max*3 diplomas of the third degree.
After some discussion it was decided to choose from all the options of distributing diplomas satisfying these limitations the one that maximizes the number of participants who receive diplomas of the first degree. Of all these options they select the one which maximizes the number of the participants who receive diplomas of the second degree. If there are multiple of these options, they select the option that maximizes the number of diplomas of the third degree.
Choosing the best option of distributing certificates was entrusted to Ilya, one of the best programmers of Berland. However, he found more important things to do, so it is your task now to choose the best option of distributing of diplomas, based on the described limitations.
It is guaranteed that the described limitations are such that there is a way to choose such an option of distributing diplomas that all *n* participants of the Olympiad will receive a diploma of some degree.
Input Specification:
The first line of the input contains a single integer *n* (3<=≤<=*n*<=≤<=3·106) — the number of schoolchildren who will participate in the Olympiad.
The next line of the input contains two integers *min*1 and *max*1 (1<=≤<=*min*1<=≤<=*max*1<=≤<=106) — the minimum and maximum limits on the number of diplomas of the first degree that can be distributed.
The third line of the input contains two integers *min*2 and *max*2 (1<=≤<=*min*2<=≤<=*max*2<=≤<=106) — the minimum and maximum limits on the number of diplomas of the second degree that can be distributed.
The next line of the input contains two integers *min*3 and *max*3 (1<=≤<=*min*3<=≤<=*max*3<=≤<=106) — the minimum and maximum limits on the number of diplomas of the third degree that can be distributed.
It is guaranteed that *min*1<=+<=*min*2<=+<=*min*3<=≤<=*n*<=≤<=*max*1<=+<=*max*2<=+<=*max*3.
Output Specification:
In the first line of the output print three numbers, showing how many diplomas of the first, second and third degree will be given to students in the optimal variant of distributing diplomas.
The optimal variant of distributing diplomas is the one that maximizes the number of students who receive diplomas of the first degree. Of all the suitable options, the best one is the one which maximizes the number of participants who receive diplomas of the second degree. If there are several of these options, the best one is the one that maximizes the number of diplomas of the third degree.
Demo Input:
['6\n1 5\n2 6\n3 7\n', '10\n1 2\n1 3\n1 5\n', '6\n1 3\n2 2\n2 2\n']
Demo Output:
['1 2 3 \n', '2 3 5 \n', '2 2 2 \n']
Note:
none
|
```python
I=lambda:map(int,input().split())
n=next(I())
a,b=I()
c,d=I()
f,e=I()
x=min(b,n-c-f)
y=min(d,n-x-f)
print(x,y,n-x-y)
```
| 3
|
|
721
|
A
|
One-dimensional Japanese Crossword
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Recently Adaltik discovered japanese crosswords. Japanese crossword is a picture, represented as a table sized *a*<=×<=*b* squares, and each square is colored white or black. There are integers to the left of the rows and to the top of the columns, encrypting the corresponding row or column. The number of integers represents how many groups of black squares there are in corresponding row or column, and the integers themselves represents the number of consecutive black squares in corresponding group (you can find more detailed explanation in Wikipedia [https://en.wikipedia.org/wiki/Japanese_crossword](https://en.wikipedia.org/wiki/Japanese_crossword)).
Adaltik decided that the general case of japanese crossword is too complicated and drew a row consisting of *n* squares (e.g. japanese crossword sized 1<=×<=*n*), which he wants to encrypt in the same way as in japanese crossword.
Help Adaltik find the numbers encrypting the row he drew.
|
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100) — the length of the row. The second line of the input contains a single string consisting of *n* characters 'B' or 'W', ('B' corresponds to black square, 'W' — to white square in the row that Adaltik drew).
|
The first line should contain a single integer *k* — the number of integers encrypting the row, e.g. the number of groups of black squares in the row.
The second line should contain *k* integers, encrypting the row, e.g. corresponding to sizes of groups of consecutive black squares in the order from left to right.
|
[
"3\nBBW\n",
"5\nBWBWB\n",
"4\nWWWW\n",
"4\nBBBB\n",
"13\nWBBBBWWBWBBBW\n"
] |
[
"1\n2 ",
"3\n1 1 1 ",
"0\n",
"1\n4 ",
"3\n4 1 3 "
] |
The last sample case correspond to the picture in the statement.
| 500
|
[
{
"input": "3\nBBW",
"output": "1\n2 "
},
{
"input": "5\nBWBWB",
"output": "3\n1 1 1 "
},
{
"input": "4\nWWWW",
"output": "0"
},
{
"input": "4\nBBBB",
"output": "1\n4 "
},
{
"input": "13\nWBBBBWWBWBBBW",
"output": "3\n4 1 3 "
},
{
"input": "1\nB",
"output": "1\n1 "
},
{
"input": "2\nBB",
"output": "1\n2 "
},
{
"input": "100\nWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWBWB",
"output": "50\n1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 "
},
{
"input": "1\nW",
"output": "0"
},
{
"input": "2\nWW",
"output": "0"
},
{
"input": "2\nWB",
"output": "1\n1 "
},
{
"input": "2\nBW",
"output": "1\n1 "
},
{
"input": "3\nBBB",
"output": "1\n3 "
},
{
"input": "3\nBWB",
"output": "2\n1 1 "
},
{
"input": "3\nWBB",
"output": "1\n2 "
},
{
"input": "3\nWWB",
"output": "1\n1 "
},
{
"input": "3\nWBW",
"output": "1\n1 "
},
{
"input": "3\nBWW",
"output": "1\n1 "
},
{
"input": "3\nWWW",
"output": "0"
},
{
"input": "100\nBBBWWWWWWBBWWBBWWWBBWBBBBBBBBBBBWBBBWBBWWWBBWWBBBWBWWBBBWWBBBWBBBBBWWWBWWBBWWWWWWBWBBWWBWWWBWBWWWWWB",
"output": "21\n3 2 2 2 11 3 2 2 3 1 3 3 5 1 2 1 2 1 1 1 1 "
},
{
"input": "5\nBBBWB",
"output": "2\n3 1 "
},
{
"input": "5\nBWWWB",
"output": "2\n1 1 "
},
{
"input": "5\nWWWWB",
"output": "1\n1 "
},
{
"input": "5\nBWWWW",
"output": "1\n1 "
},
{
"input": "5\nBBBWW",
"output": "1\n3 "
},
{
"input": "5\nWWBBB",
"output": "1\n3 "
},
{
"input": "10\nBBBBBWWBBB",
"output": "2\n5 3 "
},
{
"input": "10\nBBBBWBBWBB",
"output": "3\n4 2 2 "
},
{
"input": "20\nBBBBBWWBWBBWBWWBWBBB",
"output": "6\n5 1 2 1 1 3 "
},
{
"input": "20\nBBBWWWWBBWWWBWBWWBBB",
"output": "5\n3 2 1 1 3 "
},
{
"input": "20\nBBBBBBBBWBBBWBWBWBBB",
"output": "5\n8 3 1 1 3 "
},
{
"input": "20\nBBBWBWBWWWBBWWWWBWBB",
"output": "6\n3 1 1 2 1 2 "
},
{
"input": "40\nBBBBBBWWWWBWBWWWBWWWWWWWWWWWBBBBBBBBBBBB",
"output": "5\n6 1 1 1 12 "
},
{
"input": "40\nBBBBBWBWWWBBWWWBWBWWBBBBWWWWBWBWBBBBBBBB",
"output": "9\n5 1 2 1 1 4 1 1 8 "
},
{
"input": "50\nBBBBBBBBBBBWWWWBWBWWWWBBBBBBBBWWWWWWWBWWWWBWBBBBBB",
"output": "7\n11 1 1 8 1 1 6 "
},
{
"input": "50\nWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWW",
"output": "0"
},
{
"input": "50\nBBBBBWWWWWBWWWBWWWWWBWWWBWWWWWWBBWBBWWWWBWWWWWWWBW",
"output": "9\n5 1 1 1 1 2 2 1 1 "
},
{
"input": "50\nWWWWBWWBWWWWWWWWWWWWWWWWWWWWWWWWWBWBWBWWWWWWWBBBBB",
"output": "6\n1 1 1 1 1 5 "
},
{
"input": "50\nBBBBBWBWBWWBWBWWWWWWBWBWBWWWWWWWWWWWWWBWBWWWWBWWWB",
"output": "12\n5 1 1 1 1 1 1 1 1 1 1 1 "
},
{
"input": "50\nBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB",
"output": "1\n50 "
},
{
"input": "100\nBBBBBBBBBBBWBWWWWBWWBBWBBWWWWWWWWWWBWBWWBWWWWWWWWWWWBBBWWBBWWWWWBWBWWWWBWWWWWWWWWWWBWWWWWBBBBBBBBBBB",
"output": "15\n11 1 1 2 2 1 1 1 3 2 1 1 1 1 11 "
},
{
"input": "100\nBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB",
"output": "1\n100 "
},
{
"input": "100\nBBBBBBBBBBBBBBBBBBBBWBWBWWWWWBWWWWWWWWWWWWWWBBWWWBWWWWBWWBWWWWWWBWWWWWWWWWWWWWBWBBBBBBBBBBBBBBBBBBBB",
"output": "11\n20 1 1 1 2 1 1 1 1 1 20 "
},
{
"input": "100\nBBBBWWWWWWWWWWWWWWWWWWWWWWWWWBWBWWWWWBWBWWWWWWBBWWWWWWWWWWWWBWWWWBWWWWWWWWWWWWBWWWWWWWBWWWWWWWBBBBBB",
"output": "11\n4 1 1 1 1 2 1 1 1 1 6 "
},
{
"input": "5\nBWBWB",
"output": "3\n1 1 1 "
},
{
"input": "10\nWWBWWWBWBB",
"output": "3\n1 1 2 "
},
{
"input": "50\nBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB",
"output": "1\n50 "
},
{
"input": "50\nBBBBBBBBBBBBBBBBBWWBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB",
"output": "2\n17 31 "
},
{
"input": "100\nBBBBBBBBBBBBBBBBBBBBBBBBWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB",
"output": "2\n24 42 "
},
{
"input": "90\nWWBWWBWBBWBBWWBWBWBBBWBWBBBWBWBWBWBWBWBWBWBBBBBWBBWWWWBWBBWBWWBBBWBWBWWBWBWBWBWWWWWWBWBBBB",
"output": "30\n1 1 2 2 1 1 3 1 3 1 1 1 1 1 1 1 5 2 1 2 1 3 1 1 1 1 1 1 1 4 "
},
{
"input": "100\nBWWWBWBWBBBBBWBWWBWBWWWBWBWBWWBBWWBBBWBBBWWBWBWWBBBBWBWBBBWBWBBWWWWWWBWWBBBBWBWBWWBWBWWWBWBWWBWBWWWB",
"output": "31\n1 1 1 5 1 1 1 1 1 1 2 3 3 1 1 4 1 3 1 2 1 4 1 1 1 1 1 1 1 1 1 "
},
{
"input": "90\nWBWBBBBBBWWWBBWWBWWWBBWWBWWWBWBBWBWBBWWWWBWBWBBWBBWBWWWBBWBBWWWWBWBBWWWBBBWBBWBWBBBBWWBWWB",
"output": "25\n1 6 2 1 2 1 1 2 1 2 1 1 2 2 1 2 2 1 2 3 2 1 4 1 1 "
},
{
"input": "80\nBBWWBBBWBBWWWWBBWBWBBWWWWWBWBBWWBWBWBWBWBWWBWWBWWWBWBBWBBWBBWBBBWWBBBBBBBWBBBWBB",
"output": "23\n2 3 2 2 1 2 1 2 1 1 1 1 1 1 1 1 2 2 2 3 7 3 2 "
},
{
"input": "65\nWWWWBWWWBBBBBWWWWWWBBBWWBBBBWWWWWWWWBBBWWWWBWBWWBBWWWWBWWWBBWBBBB",
"output": "11\n1 5 3 4 3 1 1 2 1 2 4 "
}
] | 1,661,025,754
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 54
| 46
| 0
|
def main():
length = int(input())
letters = input()
black_groups_count = 0
last_letter = None
current_count = 0
second_input = ""
for letter in letters:
if letter == "B":
current_count += 1
else:
if current_count > 0:
second_input += str(current_count) + " "
current_count = 0
if letter == "B" and last_letter != "B":
black_groups_count += 1
last_letter = letter
if current_count > 0:
second_input += str(current_count) + " "
print(black_groups_count)
print(second_input)
main()
|
Title: One-dimensional Japanese Crossword
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Recently Adaltik discovered japanese crosswords. Japanese crossword is a picture, represented as a table sized *a*<=×<=*b* squares, and each square is colored white or black. There are integers to the left of the rows and to the top of the columns, encrypting the corresponding row or column. The number of integers represents how many groups of black squares there are in corresponding row or column, and the integers themselves represents the number of consecutive black squares in corresponding group (you can find more detailed explanation in Wikipedia [https://en.wikipedia.org/wiki/Japanese_crossword](https://en.wikipedia.org/wiki/Japanese_crossword)).
Adaltik decided that the general case of japanese crossword is too complicated and drew a row consisting of *n* squares (e.g. japanese crossword sized 1<=×<=*n*), which he wants to encrypt in the same way as in japanese crossword.
Help Adaltik find the numbers encrypting the row he drew.
Input Specification:
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100) — the length of the row. The second line of the input contains a single string consisting of *n* characters 'B' or 'W', ('B' corresponds to black square, 'W' — to white square in the row that Adaltik drew).
Output Specification:
The first line should contain a single integer *k* — the number of integers encrypting the row, e.g. the number of groups of black squares in the row.
The second line should contain *k* integers, encrypting the row, e.g. corresponding to sizes of groups of consecutive black squares in the order from left to right.
Demo Input:
['3\nBBW\n', '5\nBWBWB\n', '4\nWWWW\n', '4\nBBBB\n', '13\nWBBBBWWBWBBBW\n']
Demo Output:
['1\n2 ', '3\n1 1 1 ', '0\n', '1\n4 ', '3\n4 1 3 ']
Note:
The last sample case correspond to the picture in the statement.
|
```python
def main():
length = int(input())
letters = input()
black_groups_count = 0
last_letter = None
current_count = 0
second_input = ""
for letter in letters:
if letter == "B":
current_count += 1
else:
if current_count > 0:
second_input += str(current_count) + " "
current_count = 0
if letter == "B" and last_letter != "B":
black_groups_count += 1
last_letter = letter
if current_count > 0:
second_input += str(current_count) + " "
print(black_groups_count)
print(second_input)
main()
```
| 3
|
|
621
|
D
|
Rat Kwesh and Cheese
|
PROGRAMMING
| 2,400
|
[
"brute force",
"constructive algorithms",
"math"
] | null | null |
Wet Shark asked Rat Kwesh to generate three positive real numbers *x*, *y* and *z*, from 0.1 to 200.0, inclusive. Wet Krash wants to impress Wet Shark, so all generated numbers will have exactly one digit after the decimal point.
Wet Shark knows Rat Kwesh will want a lot of cheese. So he will give the Rat an opportunity to earn a lot of cheese. He will hand the three numbers *x*, *y* and *z* to Rat Kwesh, and Rat Kwesh will pick one of the these twelve options:
1. *a*1<==<=*x**y**z*; 1. *a*2<==<=*x**z**y*; 1. *a*3<==<=(*x**y*)*z*; 1. *a*4<==<=(*x**z*)*y*; 1. *a*5<==<=*y**x**z*; 1. *a*6<==<=*y**z**x*; 1. *a*7<==<=(*y**x*)*z*; 1. *a*8<==<=(*y**z*)*x*; 1. *a*9<==<=*z**x**y*; 1. *a*10<==<=*z**y**x*; 1. *a*11<==<=(*z**x*)*y*; 1. *a*12<==<=(*z**y*)*x*.
Let *m* be the maximum of all the *a**i*, and *c* be the smallest index (from 1 to 12) such that *a**c*<==<=*m*. Rat's goal is to find that *c*, and he asks you to help him. Rat Kwesh wants to see how much cheese he gets, so he you will have to print the expression corresponding to that *a**c*.
|
The only line of the input contains three space-separated real numbers *x*, *y* and *z* (0.1<=≤<=*x*,<=*y*,<=*z*<=≤<=200.0). Each of *x*, *y* and *z* is given with exactly one digit after the decimal point.
|
Find the maximum value of expression among *x**y**z*, *x**z**y*, (*x**y*)*z*, (*x**z*)*y*, *y**x**z*, *y**z**x*, (*y**x*)*z*, (*y**z*)*x*, *z**x**y*, *z**y**x*, (*z**x*)*y*, (*z**y*)*x* and print the corresponding expression. If there are many maximums, print the one that comes first in the list.
*x**y**z* should be outputted as x^y^z (without brackets), and (*x**y*)*z* should be outputted as (x^y)^z (quotes for clarity).
|
[
"1.1 3.4 2.5\n",
"2.0 2.0 2.0\n",
"1.9 1.8 1.7\n"
] |
[
"z^y^x\n",
"x^y^z\n",
"(x^y)^z\n"
] |
none
| 2,000
|
[
{
"input": "1.1 3.4 2.5",
"output": "z^y^x"
},
{
"input": "2.0 2.0 2.0",
"output": "x^y^z"
},
{
"input": "1.9 1.8 1.7",
"output": "(x^y)^z"
},
{
"input": "2.0 2.1 2.2",
"output": "x^z^y"
},
{
"input": "1.5 1.7 2.5",
"output": "(z^x)^y"
},
{
"input": "1.1 1.1 1.1",
"output": "(x^y)^z"
},
{
"input": "4.2 1.1 1.2",
"output": "(x^y)^z"
},
{
"input": "113.9 125.2 88.8",
"output": "z^x^y"
},
{
"input": "185.9 9.6 163.4",
"output": "y^z^x"
},
{
"input": "198.7 23.7 89.1",
"output": "y^z^x"
},
{
"input": "141.1 108.1 14.9",
"output": "z^y^x"
},
{
"input": "153.9 122.1 89.5",
"output": "z^y^x"
},
{
"input": "25.9 77.0 144.8",
"output": "x^y^z"
},
{
"input": "38.7 142.2 89.8",
"output": "x^z^y"
},
{
"input": "51.5 156.3 145.1",
"output": "x^z^y"
},
{
"input": "193.9 40.7 19.7",
"output": "z^y^x"
},
{
"input": "51.8 51.8 7.1",
"output": "z^x^y"
},
{
"input": "64.6 117.1 81.6",
"output": "x^z^y"
},
{
"input": "7.0 131.1 7.4",
"output": "x^z^y"
},
{
"input": "149.4 15.5 82.0",
"output": "y^z^x"
},
{
"input": "91.8 170.4 7.7",
"output": "z^x^y"
},
{
"input": "104.6 184.4 82.3",
"output": "z^x^y"
},
{
"input": "117.4 68.8 137.7",
"output": "y^x^z"
},
{
"input": "189.4 63.7 63.4",
"output": "z^y^x"
},
{
"input": "2.2 148.1 138.0",
"output": "x^z^y"
},
{
"input": "144.6 103.0 193.4",
"output": "y^x^z"
},
{
"input": "144.0 70.4 148.1",
"output": "y^x^z"
},
{
"input": "156.9 154.8 73.9",
"output": "z^y^x"
},
{
"input": "28.9 39.3 148.4",
"output": "x^y^z"
},
{
"input": "41.7 104.5 74.2",
"output": "x^z^y"
},
{
"input": "184.1 118.5 129.5",
"output": "y^z^x"
},
{
"input": "196.9 3.0 4.1",
"output": "y^z^x"
},
{
"input": "139.3 87.4 129.9",
"output": "y^z^x"
},
{
"input": "81.7 171.9 4.4",
"output": "z^x^y"
},
{
"input": "94.5 56.3 59.8",
"output": "y^z^x"
},
{
"input": "36.9 51.1 4.8",
"output": "z^x^y"
},
{
"input": "55.5 159.4 140.3",
"output": "x^z^y"
},
{
"input": "3.9 0.2 3.8",
"output": "x^z^y"
},
{
"input": "0.9 4.6 3.4",
"output": "(z^x)^y"
},
{
"input": "3.7 3.7 4.1",
"output": "x^y^z"
},
{
"input": "1.1 3.1 4.9",
"output": "x^y^z"
},
{
"input": "3.9 2.1 4.5",
"output": "y^x^z"
},
{
"input": "0.9 2.0 4.8",
"output": "(y^x)^z"
},
{
"input": "3.7 2.2 4.8",
"output": "y^x^z"
},
{
"input": "1.5 1.3 0.1",
"output": "x^y^z"
},
{
"input": "3.9 0.7 4.7",
"output": "(x^y)^z"
},
{
"input": "1.8 1.8 2.1",
"output": "(z^x)^y"
},
{
"input": "4.6 2.1 1.6",
"output": "z^y^x"
},
{
"input": "2.0 1.1 2.4",
"output": "(z^x)^y"
},
{
"input": "4.4 0.5 2.0",
"output": "x^z^y"
},
{
"input": "1.8 0.4 2.7",
"output": "z^x^y"
},
{
"input": "4.6 4.4 2.3",
"output": "z^y^x"
},
{
"input": "2.4 3.8 2.7",
"output": "x^z^y"
},
{
"input": "4.4 3.7 3.4",
"output": "z^y^x"
},
{
"input": "2.2 3.1 3.0",
"output": "x^z^y"
},
{
"input": "4.6 3.0 3.4",
"output": "y^z^x"
},
{
"input": "4.0 0.4 3.1",
"output": "x^z^y"
},
{
"input": "1.9 4.8 3.9",
"output": "x^z^y"
},
{
"input": "3.9 4.3 3.4",
"output": "z^x^y"
},
{
"input": "1.7 4.5 4.2",
"output": "x^z^y"
},
{
"input": "4.1 3.5 4.5",
"output": "y^x^z"
},
{
"input": "1.9 3.0 4.1",
"output": "x^y^z"
},
{
"input": "4.3 2.4 4.9",
"output": "y^x^z"
},
{
"input": "1.7 1.9 4.4",
"output": "x^y^z"
},
{
"input": "4.5 1.3 4.8",
"output": "y^x^z"
},
{
"input": "1.9 1.1 4.8",
"output": "x^z^y"
},
{
"input": "0.4 0.2 0.3",
"output": "(x^y)^z"
},
{
"input": "0.4 1.1 0.9",
"output": "y^z^x"
},
{
"input": "0.2 0.7 0.6",
"output": "(y^x)^z"
},
{
"input": "0.1 0.1 0.4",
"output": "(z^x)^y"
},
{
"input": "1.4 1.1 1.0",
"output": "x^y^z"
},
{
"input": "1.4 0.5 0.8",
"output": "x^z^y"
},
{
"input": "1.2 0.7 1.3",
"output": "z^x^y"
},
{
"input": "1.0 0.3 1.1",
"output": "z^x^y"
},
{
"input": "0.9 1.2 0.2",
"output": "y^x^z"
},
{
"input": "0.8 0.3 0.6",
"output": "(x^y)^z"
},
{
"input": "0.6 0.6 1.1",
"output": "z^x^y"
},
{
"input": "0.5 0.1 0.9",
"output": "(z^x)^y"
},
{
"input": "0.4 1.0 1.5",
"output": "z^y^x"
},
{
"input": "0.3 0.4 1.2",
"output": "z^y^x"
},
{
"input": "0.1 1.4 0.3",
"output": "y^z^x"
},
{
"input": "1.4 0.8 0.2",
"output": "x^y^z"
},
{
"input": "1.4 1.2 1.4",
"output": "(x^y)^z"
},
{
"input": "1.2 0.6 0.5",
"output": "x^y^z"
},
{
"input": "1.1 1.5 0.4",
"output": "y^x^z"
},
{
"input": "1.5 1.4 1.1",
"output": "(x^y)^z"
},
{
"input": "1.4 0.8 0.9",
"output": "x^z^y"
},
{
"input": "1.4 0.3 1.4",
"output": "x^z^y"
},
{
"input": "1.2 0.5 1.2",
"output": "x^z^y"
},
{
"input": "1.1 1.5 1.0",
"output": "y^x^z"
},
{
"input": "0.9 1.0 0.1",
"output": "y^x^z"
},
{
"input": "0.8 0.4 1.4",
"output": "z^x^y"
},
{
"input": "0.7 1.4 0.4",
"output": "y^x^z"
},
{
"input": "0.5 0.8 0.3",
"output": "(y^x)^z"
},
{
"input": "0.4 1.1 0.8",
"output": "y^z^x"
},
{
"input": "0.2 0.1 0.2",
"output": "(x^y)^z"
},
{
"input": "0.1 0.2 0.6",
"output": "(z^x)^y"
},
{
"input": "0.1 0.2 0.6",
"output": "(z^x)^y"
},
{
"input": "0.5 0.1 0.3",
"output": "(x^y)^z"
},
{
"input": "0.1 0.1 0.1",
"output": "(x^y)^z"
},
{
"input": "0.5 0.5 0.1",
"output": "(x^y)^z"
},
{
"input": "0.5 0.2 0.2",
"output": "(x^y)^z"
},
{
"input": "0.3 0.4 0.4",
"output": "(y^x)^z"
},
{
"input": "0.1 0.3 0.5",
"output": "(z^x)^y"
},
{
"input": "0.3 0.3 0.5",
"output": "(z^x)^y"
},
{
"input": "0.2 0.6 0.3",
"output": "(y^x)^z"
},
{
"input": "0.6 0.3 0.2",
"output": "(x^y)^z"
},
{
"input": "0.2 0.1 0.6",
"output": "(z^x)^y"
},
{
"input": "0.4 0.1 0.6",
"output": "(z^x)^y"
},
{
"input": "0.6 0.4 0.3",
"output": "(x^y)^z"
},
{
"input": "0.4 0.2 0.3",
"output": "(x^y)^z"
},
{
"input": "0.2 0.2 0.5",
"output": "(z^x)^y"
},
{
"input": "0.2 0.3 0.2",
"output": "(y^x)^z"
},
{
"input": "0.6 0.3 0.2",
"output": "(x^y)^z"
},
{
"input": "0.2 0.6 0.4",
"output": "(y^x)^z"
},
{
"input": "0.6 0.2 0.5",
"output": "(x^y)^z"
},
{
"input": "0.5 0.2 0.3",
"output": "(x^y)^z"
},
{
"input": "0.5 0.3 0.2",
"output": "(x^y)^z"
},
{
"input": "0.3 0.5 0.6",
"output": "(z^x)^y"
},
{
"input": "0.5 0.3 0.1",
"output": "(x^y)^z"
},
{
"input": "0.3 0.4 0.1",
"output": "(y^x)^z"
},
{
"input": "0.5 0.4 0.5",
"output": "(x^y)^z"
},
{
"input": "0.1 0.5 0.4",
"output": "(y^x)^z"
},
{
"input": "0.5 0.5 0.6",
"output": "(z^x)^y"
},
{
"input": "0.1 0.5 0.2",
"output": "(y^x)^z"
},
{
"input": "1.0 2.0 4.0",
"output": "y^z^x"
},
{
"input": "1.0 4.0 2.0",
"output": "y^z^x"
},
{
"input": "2.0 1.0 4.0",
"output": "x^z^y"
},
{
"input": "2.0 4.0 1.0",
"output": "x^y^z"
},
{
"input": "4.0 1.0 2.0",
"output": "x^z^y"
},
{
"input": "4.0 2.0 1.0",
"output": "x^y^z"
},
{
"input": "3.0 3.0 3.1",
"output": "x^y^z"
},
{
"input": "0.1 0.2 0.3",
"output": "(z^x)^y"
},
{
"input": "200.0 200.0 200.0",
"output": "x^y^z"
},
{
"input": "1.0 1.0 200.0",
"output": "z^x^y"
},
{
"input": "1.0 200.0 1.0",
"output": "y^x^z"
},
{
"input": "200.0 1.0 1.0",
"output": "x^y^z"
},
{
"input": "200.0 200.0 1.0",
"output": "x^y^z"
},
{
"input": "200.0 1.0 200.0",
"output": "x^z^y"
},
{
"input": "1.0 200.0 200.0",
"output": "y^z^x"
},
{
"input": "1.0 1.0 1.0",
"output": "x^y^z"
},
{
"input": "200.0 0.1 0.1",
"output": "x^y^z"
},
{
"input": "200.0 0.1 200.0",
"output": "(x^y)^z"
},
{
"input": "0.1 200.0 200.0",
"output": "(y^x)^z"
},
{
"input": "200.0 200.0 0.1",
"output": "(x^y)^z"
},
{
"input": "0.1 200.0 0.1",
"output": "y^x^z"
},
{
"input": "0.1 0.1 200.0",
"output": "z^x^y"
},
{
"input": "0.1 0.1 0.1",
"output": "(x^y)^z"
},
{
"input": "0.1 0.4 0.2",
"output": "(y^x)^z"
},
{
"input": "0.2 0.3 0.1",
"output": "(y^x)^z"
},
{
"input": "0.1 0.4 0.3",
"output": "(y^x)^z"
},
{
"input": "1.0 2.0 1.0",
"output": "y^x^z"
}
] | 1,609,141,867
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 152
| 155
| 0
|
import math
ar=list(map(float,input().split()))
mn=-float('inf')
mns=""
def xyz(x,y,z,op):
if(op==1):
return (x**y**z,"x^y^z")
elif(op==2):
return (x**z**y,"x^z^y")
elif(op==5):
return (y**x**z,"y^x^z")
elif(op==6):
return (y**z**x,"y^z^x")
elif(op==9):
return (z**x**y,"z^x^y")
elif(op==10):
return (z**y**x,"z^y^x")
elif(op==3):
return ((x**y)**z,"(x^y)^z")
elif(op==4):
return ((x**z)**y,"(x^z)^y")
elif(op==7):
return ((y**x)**z,"(y^x)^z")
elif(op==8):
return ((y**z)**x,"(y^z)^x")
elif(op==11):
return ((z**x)**y,"(z^x)^y")
elif(op==12):
return ((z**y)**x,"(z^y)^x")
def xyz2(x,y,z,op):
if(op==1):
try:
vl=math.log2(math.log2(x))+math.log2(y)*z
except:
vl=-float('inf')
return (vl,"x^y^z")
elif(op==2):
try:
vl=math.log2(math.log2(x))+math.log2(z)*y
except:
vl=-float('inf')
return (vl,"x^z^y")
elif(op==5):
try:
vl=math.log2(math.log2(y))+math.log2(x)*z
except:
vl=-float('inf')
return (vl,"y^x^z")
elif(op==6):
try:
vl=math.log2(math.log2(y))+math.log2(z)*x
except:
vl=-float('inf')
return (vl,"y^z^x")
elif(op==9):
try:
vl=math.log2(math.log2(z))+math.log2(x)*y
except:
vl=-float('inf')
return (vl,"z^x^y")
elif(op==10):
try:
vl=math.log2(math.log2(z))+math.log2(y)*x
except:
vl=-float('inf')
return (vl,"z^y^x")
elif(op==3):
try:
vl=math.log2(math.log2(x))+math.log2(y)+math.log2(z)
except:
vl=-float('inf')
return (vl,"(x^y)^z")
elif(op==4):
try:
vl=math.log2(math.log2(x))+math.log2(z)+math.log2(y)
except:
vl=-float('inf')
return (vl,"(x^z)^y")
elif(op==7):
try:
vl=math.log2(math.log2(y))+math.log2(x)+math.log2(z)
except:
vl=-float('inf')
return (vl,"(y^x)^z")
elif(op==8):
try:
vl=math.log2(math.log2(y))+math.log2(x)+math.log2(z)
except:
vl=-float('inf')
return (vl,"(y^z)^x")
elif(op==11):
try:
vl=math.log2(math.log2(z))+math.log2(x)+math.log2(y)
except:
vl=-float('inf')
return (vl,"(z^x)^y")
elif(op==12):
try:
vl=math.log2(math.log2(z))+math.log2(x)+math.log2(y)
except:
vl=-float('inf')
return (vl,"(z^y)^x")
E=[[0,1,2],[0,2,1],[1,0,2],[1,2,0],[2,0,1],[2,1,0]]
if(max(ar)<4.1):
for i in range(1,13):
a=xyz(ar[0],ar[1],ar[2],i)
#print(a)
if(a[0]-1e-7>mn):
mn=a[0]
mns=a[1]
else:
for i in range(1,13):
a=xyz2(ar[0],ar[1],ar[2],i)
#print(a)
if(a[0]-1e-7>mn):
mn=a[0]
mns=a[1]
print(mns)
|
Title: Rat Kwesh and Cheese
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Wet Shark asked Rat Kwesh to generate three positive real numbers *x*, *y* and *z*, from 0.1 to 200.0, inclusive. Wet Krash wants to impress Wet Shark, so all generated numbers will have exactly one digit after the decimal point.
Wet Shark knows Rat Kwesh will want a lot of cheese. So he will give the Rat an opportunity to earn a lot of cheese. He will hand the three numbers *x*, *y* and *z* to Rat Kwesh, and Rat Kwesh will pick one of the these twelve options:
1. *a*1<==<=*x**y**z*; 1. *a*2<==<=*x**z**y*; 1. *a*3<==<=(*x**y*)*z*; 1. *a*4<==<=(*x**z*)*y*; 1. *a*5<==<=*y**x**z*; 1. *a*6<==<=*y**z**x*; 1. *a*7<==<=(*y**x*)*z*; 1. *a*8<==<=(*y**z*)*x*; 1. *a*9<==<=*z**x**y*; 1. *a*10<==<=*z**y**x*; 1. *a*11<==<=(*z**x*)*y*; 1. *a*12<==<=(*z**y*)*x*.
Let *m* be the maximum of all the *a**i*, and *c* be the smallest index (from 1 to 12) such that *a**c*<==<=*m*. Rat's goal is to find that *c*, and he asks you to help him. Rat Kwesh wants to see how much cheese he gets, so he you will have to print the expression corresponding to that *a**c*.
Input Specification:
The only line of the input contains three space-separated real numbers *x*, *y* and *z* (0.1<=≤<=*x*,<=*y*,<=*z*<=≤<=200.0). Each of *x*, *y* and *z* is given with exactly one digit after the decimal point.
Output Specification:
Find the maximum value of expression among *x**y**z*, *x**z**y*, (*x**y*)*z*, (*x**z*)*y*, *y**x**z*, *y**z**x*, (*y**x*)*z*, (*y**z*)*x*, *z**x**y*, *z**y**x*, (*z**x*)*y*, (*z**y*)*x* and print the corresponding expression. If there are many maximums, print the one that comes first in the list.
*x**y**z* should be outputted as x^y^z (without brackets), and (*x**y*)*z* should be outputted as (x^y)^z (quotes for clarity).
Demo Input:
['1.1 3.4 2.5\n', '2.0 2.0 2.0\n', '1.9 1.8 1.7\n']
Demo Output:
['z^y^x\n', 'x^y^z\n', '(x^y)^z\n']
Note:
none
|
```python
import math
ar=list(map(float,input().split()))
mn=-float('inf')
mns=""
def xyz(x,y,z,op):
if(op==1):
return (x**y**z,"x^y^z")
elif(op==2):
return (x**z**y,"x^z^y")
elif(op==5):
return (y**x**z,"y^x^z")
elif(op==6):
return (y**z**x,"y^z^x")
elif(op==9):
return (z**x**y,"z^x^y")
elif(op==10):
return (z**y**x,"z^y^x")
elif(op==3):
return ((x**y)**z,"(x^y)^z")
elif(op==4):
return ((x**z)**y,"(x^z)^y")
elif(op==7):
return ((y**x)**z,"(y^x)^z")
elif(op==8):
return ((y**z)**x,"(y^z)^x")
elif(op==11):
return ((z**x)**y,"(z^x)^y")
elif(op==12):
return ((z**y)**x,"(z^y)^x")
def xyz2(x,y,z,op):
if(op==1):
try:
vl=math.log2(math.log2(x))+math.log2(y)*z
except:
vl=-float('inf')
return (vl,"x^y^z")
elif(op==2):
try:
vl=math.log2(math.log2(x))+math.log2(z)*y
except:
vl=-float('inf')
return (vl,"x^z^y")
elif(op==5):
try:
vl=math.log2(math.log2(y))+math.log2(x)*z
except:
vl=-float('inf')
return (vl,"y^x^z")
elif(op==6):
try:
vl=math.log2(math.log2(y))+math.log2(z)*x
except:
vl=-float('inf')
return (vl,"y^z^x")
elif(op==9):
try:
vl=math.log2(math.log2(z))+math.log2(x)*y
except:
vl=-float('inf')
return (vl,"z^x^y")
elif(op==10):
try:
vl=math.log2(math.log2(z))+math.log2(y)*x
except:
vl=-float('inf')
return (vl,"z^y^x")
elif(op==3):
try:
vl=math.log2(math.log2(x))+math.log2(y)+math.log2(z)
except:
vl=-float('inf')
return (vl,"(x^y)^z")
elif(op==4):
try:
vl=math.log2(math.log2(x))+math.log2(z)+math.log2(y)
except:
vl=-float('inf')
return (vl,"(x^z)^y")
elif(op==7):
try:
vl=math.log2(math.log2(y))+math.log2(x)+math.log2(z)
except:
vl=-float('inf')
return (vl,"(y^x)^z")
elif(op==8):
try:
vl=math.log2(math.log2(y))+math.log2(x)+math.log2(z)
except:
vl=-float('inf')
return (vl,"(y^z)^x")
elif(op==11):
try:
vl=math.log2(math.log2(z))+math.log2(x)+math.log2(y)
except:
vl=-float('inf')
return (vl,"(z^x)^y")
elif(op==12):
try:
vl=math.log2(math.log2(z))+math.log2(x)+math.log2(y)
except:
vl=-float('inf')
return (vl,"(z^y)^x")
E=[[0,1,2],[0,2,1],[1,0,2],[1,2,0],[2,0,1],[2,1,0]]
if(max(ar)<4.1):
for i in range(1,13):
a=xyz(ar[0],ar[1],ar[2],i)
#print(a)
if(a[0]-1e-7>mn):
mn=a[0]
mns=a[1]
else:
for i in range(1,13):
a=xyz2(ar[0],ar[1],ar[2],i)
#print(a)
if(a[0]-1e-7>mn):
mn=a[0]
mns=a[1]
print(mns)
```
| 3
|
|
769
|
A
|
Year of University Entrance
|
PROGRAMMING
| 800
|
[
"*special",
"implementation",
"sortings"
] | null | null |
There is the faculty of Computer Science in Berland. In the social net "TheContact!" for each course of this faculty there is the special group whose name equals the year of university entrance of corresponding course of students at the university.
Each of students joins the group of his course and joins all groups for which the year of student's university entrance differs by no more than *x* from the year of university entrance of this student, where *x* — some non-negative integer. A value *x* is not given, but it can be uniquely determined from the available data. Note that students don't join other groups.
You are given the list of groups which the student Igor joined. According to this information you need to determine the year of Igor's university entrance.
|
The first line contains the positive odd integer *n* (1<=≤<=*n*<=≤<=5) — the number of groups which Igor joined.
The next line contains *n* distinct integers *a*1,<=*a*2,<=...,<=*a**n* (2010<=≤<=*a**i*<=≤<=2100) — years of student's university entrance for each group in which Igor is the member.
It is guaranteed that the input data is correct and the answer always exists. Groups are given randomly.
|
Print the year of Igor's university entrance.
|
[
"3\n2014 2016 2015\n",
"1\n2050\n"
] |
[
"2015\n",
"2050\n"
] |
In the first test the value *x* = 1. Igor entered the university in 2015. So he joined groups members of which are students who entered the university in 2014, 2015 and 2016.
In the second test the value *x* = 0. Igor entered only the group which corresponds to the year of his university entrance.
| 500
|
[
{
"input": "3\n2014 2016 2015",
"output": "2015"
},
{
"input": "1\n2050",
"output": "2050"
},
{
"input": "1\n2010",
"output": "2010"
},
{
"input": "1\n2011",
"output": "2011"
},
{
"input": "3\n2010 2011 2012",
"output": "2011"
},
{
"input": "3\n2049 2047 2048",
"output": "2048"
},
{
"input": "5\n2043 2042 2041 2044 2040",
"output": "2042"
},
{
"input": "5\n2012 2013 2014 2015 2016",
"output": "2014"
},
{
"input": "1\n2045",
"output": "2045"
},
{
"input": "1\n2046",
"output": "2046"
},
{
"input": "1\n2099",
"output": "2099"
},
{
"input": "1\n2100",
"output": "2100"
},
{
"input": "3\n2011 2010 2012",
"output": "2011"
},
{
"input": "3\n2011 2012 2010",
"output": "2011"
},
{
"input": "3\n2012 2011 2010",
"output": "2011"
},
{
"input": "3\n2010 2012 2011",
"output": "2011"
},
{
"input": "3\n2012 2010 2011",
"output": "2011"
},
{
"input": "3\n2047 2048 2049",
"output": "2048"
},
{
"input": "3\n2047 2049 2048",
"output": "2048"
},
{
"input": "3\n2048 2047 2049",
"output": "2048"
},
{
"input": "3\n2048 2049 2047",
"output": "2048"
},
{
"input": "3\n2049 2048 2047",
"output": "2048"
},
{
"input": "5\n2011 2014 2012 2013 2010",
"output": "2012"
},
{
"input": "5\n2014 2013 2011 2012 2015",
"output": "2013"
},
{
"input": "5\n2021 2023 2024 2020 2022",
"output": "2022"
},
{
"input": "5\n2081 2079 2078 2080 2077",
"output": "2079"
},
{
"input": "5\n2095 2099 2097 2096 2098",
"output": "2097"
},
{
"input": "5\n2097 2099 2100 2098 2096",
"output": "2098"
},
{
"input": "5\n2012 2010 2014 2011 2013",
"output": "2012"
},
{
"input": "5\n2012 2011 2013 2015 2014",
"output": "2013"
},
{
"input": "5\n2023 2024 2022 2021 2020",
"output": "2022"
},
{
"input": "5\n2077 2078 2080 2079 2081",
"output": "2079"
},
{
"input": "5\n2099 2096 2095 2097 2098",
"output": "2097"
},
{
"input": "5\n2097 2100 2098 2096 2099",
"output": "2098"
},
{
"input": "5\n2011 2014 2013 2010 2012",
"output": "2012"
},
{
"input": "5\n2013 2011 2015 2012 2014",
"output": "2013"
},
{
"input": "5\n2024 2020 2021 2023 2022",
"output": "2022"
},
{
"input": "5\n2079 2080 2077 2081 2078",
"output": "2079"
},
{
"input": "5\n2095 2097 2096 2098 2099",
"output": "2097"
},
{
"input": "5\n2099 2096 2100 2097 2098",
"output": "2098"
},
{
"input": "5\n2034 2033 2036 2032 2035",
"output": "2034"
},
{
"input": "5\n2030 2031 2033 2032 2029",
"output": "2031"
},
{
"input": "5\n2093 2092 2094 2096 2095",
"output": "2094"
},
{
"input": "5\n2012 2015 2014 2013 2011",
"output": "2013"
},
{
"input": "5\n2056 2057 2058 2059 2060",
"output": "2058"
}
] | 1,488,643,184
| 14,384
|
Python 3
|
OK
|
TESTS
| 45
| 62
| 4,608,000
|
a = int(input()) // 2
arr = list(map(int, input().split()))
arr.sort()
print(arr[a])
|
Title: Year of University Entrance
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There is the faculty of Computer Science in Berland. In the social net "TheContact!" for each course of this faculty there is the special group whose name equals the year of university entrance of corresponding course of students at the university.
Each of students joins the group of his course and joins all groups for which the year of student's university entrance differs by no more than *x* from the year of university entrance of this student, where *x* — some non-negative integer. A value *x* is not given, but it can be uniquely determined from the available data. Note that students don't join other groups.
You are given the list of groups which the student Igor joined. According to this information you need to determine the year of Igor's university entrance.
Input Specification:
The first line contains the positive odd integer *n* (1<=≤<=*n*<=≤<=5) — the number of groups which Igor joined.
The next line contains *n* distinct integers *a*1,<=*a*2,<=...,<=*a**n* (2010<=≤<=*a**i*<=≤<=2100) — years of student's university entrance for each group in which Igor is the member.
It is guaranteed that the input data is correct and the answer always exists. Groups are given randomly.
Output Specification:
Print the year of Igor's university entrance.
Demo Input:
['3\n2014 2016 2015\n', '1\n2050\n']
Demo Output:
['2015\n', '2050\n']
Note:
In the first test the value *x* = 1. Igor entered the university in 2015. So he joined groups members of which are students who entered the university in 2014, 2015 and 2016.
In the second test the value *x* = 0. Igor entered only the group which corresponds to the year of his university entrance.
|
```python
a = int(input()) // 2
arr = list(map(int, input().split()))
arr.sort()
print(arr[a])
```
| 3
|
|
490
|
A
|
Team Olympiad
|
PROGRAMMING
| 800
|
[
"greedy",
"implementation",
"sortings"
] | null | null |
The School №0 of the capital of Berland has *n* children studying in it. All the children in this school are gifted: some of them are good at programming, some are good at maths, others are good at PE (Physical Education). Hence, for each child we know value *t**i*:
- *t**i*<==<=1, if the *i*-th child is good at programming, - *t**i*<==<=2, if the *i*-th child is good at maths, - *t**i*<==<=3, if the *i*-th child is good at PE
Each child happens to be good at exactly one of these three subjects.
The Team Scientific Decathlon Olympias requires teams of three students. The school teachers decided that the teams will be composed of three children that are good at different subjects. That is, each team must have one mathematician, one programmer and one sportsman. Of course, each child can be a member of no more than one team.
What is the maximum number of teams that the school will be able to present at the Olympiad? How should the teams be formed for that?
|
The first line contains integer *n* (1<=≤<=*n*<=≤<=5000) — the number of children in the school. The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t**i*<=≤<=3), where *t**i* describes the skill of the *i*-th child.
|
In the first line output integer *w* — the largest possible number of teams.
Then print *w* lines, containing three numbers in each line. Each triple represents the indexes of the children forming the team. You can print both the teams, and the numbers in the triplets in any order. The children are numbered from 1 to *n* in the order of their appearance in the input. Each child must participate in no more than one team. If there are several solutions, print any of them.
If no teams can be compiled, print the only line with value *w* equal to 0.
|
[
"7\n1 3 1 3 2 1 2\n",
"4\n2 1 1 2\n"
] |
[
"2\n3 5 2\n6 7 4\n",
"0\n"
] |
none
| 500
|
[
{
"input": "7\n1 3 1 3 2 1 2",
"output": "2\n3 5 2\n6 7 4"
},
{
"input": "4\n2 1 1 2",
"output": "0"
},
{
"input": "1\n2",
"output": "0"
},
{
"input": "2\n3 1",
"output": "0"
},
{
"input": "3\n2 1 2",
"output": "0"
},
{
"input": "3\n1 2 3",
"output": "1\n1 2 3"
},
{
"input": "12\n3 3 3 3 3 3 3 3 1 3 3 2",
"output": "1\n9 12 2"
},
{
"input": "60\n3 3 1 2 2 1 3 1 1 1 3 2 2 2 3 3 1 3 2 3 2 2 1 3 3 2 3 1 2 2 2 1 3 2 1 1 3 3 1 1 1 3 1 2 1 1 3 3 3 2 3 2 3 2 2 2 1 1 1 2",
"output": "20\n6 60 1\n17 44 20\n3 5 33\n36 21 42\n59 14 2\n58 26 49\n9 29 48\n23 19 24\n10 30 37\n41 54 15\n45 31 27\n57 55 38\n39 12 25\n35 34 11\n32 52 7\n8 50 18\n43 4 53\n46 56 51\n40 22 16\n28 13 47"
},
{
"input": "12\n3 1 1 1 1 1 1 2 1 1 1 1",
"output": "1\n3 8 1"
},
{
"input": "22\n2 2 2 2 2 2 2 2 2 2 3 2 2 2 2 2 2 1 2 2 2 2",
"output": "1\n18 2 11"
},
{
"input": "138\n2 3 2 2 2 2 2 2 2 2 1 2 1 2 2 2 1 2 1 2 2 1 2 2 2 2 2 2 2 2 2 2 2 1 2 3 2 2 2 1 2 3 2 2 2 3 1 3 2 3 2 3 2 2 2 2 3 2 2 2 2 2 1 2 2 3 2 2 3 2 1 2 2 2 2 2 3 1 2 2 2 2 2 3 2 2 3 2 2 2 2 2 1 1 2 3 2 2 2 2 3 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 3 2 3 2 2 2 1 2 2 2 1 2 2 2 2 1 2 2 2 2 1 3",
"output": "18\n13 91 84\n34 90 48\n11 39 77\n78 129 50\n137 68 119\n132 122 138\n19 12 96\n40 7 2\n22 88 69\n107 73 46\n115 15 52\n127 106 87\n93 92 66\n71 112 117\n63 124 42\n17 70 101\n109 121 57\n123 25 36"
},
{
"input": "203\n2 2 1 2 1 2 2 2 1 2 2 1 1 3 1 2 1 2 1 1 2 3 1 1 2 3 3 2 2 2 1 2 1 1 1 1 1 3 1 1 2 1 1 2 2 2 1 2 2 2 1 2 3 2 1 1 2 2 1 2 1 2 2 1 1 2 2 2 1 1 2 2 1 2 1 2 2 3 2 1 2 1 1 1 1 1 1 1 1 1 1 2 2 1 1 2 2 2 2 1 1 1 1 1 1 1 2 2 2 2 2 1 1 1 2 2 2 1 2 2 1 3 2 1 1 1 2 1 1 2 1 1 2 2 2 1 1 2 2 2 1 2 1 3 2 1 2 2 2 1 1 1 2 2 2 1 2 1 1 2 2 2 2 2 1 1 2 1 2 2 1 1 1 1 1 1 2 2 3 1 1 2 3 1 1 1 1 1 1 2 2 1 1 1 2 2 3 2 1 3 1 1 1",
"output": "13\n188 72 14\n137 4 197\n158 76 122\n152 142 26\n104 119 179\n40 63 38\n12 1 78\n17 30 27\n189 60 53\n166 190 144\n129 7 183\n83 41 22\n121 81 200"
},
{
"input": "220\n1 1 3 1 3 1 1 3 1 3 3 3 3 1 3 3 1 3 3 3 3 3 1 1 1 3 1 1 1 3 2 3 3 3 1 1 3 3 1 1 3 3 3 3 1 3 3 1 1 1 2 3 1 1 1 2 3 3 3 2 3 1 1 3 1 1 1 3 2 1 3 2 3 1 1 3 3 3 1 3 1 1 1 3 3 2 1 3 2 1 1 3 3 1 1 1 2 1 1 3 2 1 2 1 1 1 3 1 3 3 1 2 3 3 3 3 1 3 1 1 1 1 2 3 1 1 1 1 1 1 3 2 3 1 3 1 3 1 1 3 1 3 1 3 1 3 1 3 3 2 3 1 3 3 1 3 3 3 3 1 1 3 3 3 3 1 1 3 3 3 2 1 1 1 3 3 1 3 3 3 1 1 1 3 1 3 3 1 1 1 2 3 1 1 3 1 1 1 1 2 3 1 1 2 3 3 1 3 1 3 3 3 3 1 3 2 3 1 1 3",
"output": "20\n198 89 20\n141 56 131\n166 204 19\n160 132 142\n111 112 195\n45 216 92\n6 31 109\n14 150 170\n199 60 18\n173 123 140\n134 69 156\n82 191 85\n126 200 80\n24 97 46\n62 86 149\n214 101 26\n79 171 78\n125 72 118\n172 103 162\n219 51 64"
},
{
"input": "61\n2 3 1 3 2 2 2 3 1 3 2 3 1 2 1 1 2 2 2 2 3 2 3 1 2 1 3 1 3 2 1 1 3 2 1 3 3 3 1 3 3 1 1 3 1 3 2 2 1 2 2 2 1 3 2 3 1 3 3 1 1",
"output": "20\n9 55 2\n24 34 27\n3 5 37\n35 17 41\n61 11 4\n60 19 54\n15 20 59\n26 14 29\n16 22 38\n43 50 12\n49 25 36\n57 51 40\n39 6 33\n32 30 10\n31 48 8\n13 47 23\n45 1 58\n53 52 56\n42 18 21\n28 7 44"
},
{
"input": "5\n1 2 2 3 3",
"output": "1\n1 3 4"
}
] | 1,699,134,568
| 2,147,483,647
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 0
| 30
| 0
|
n = int(input())
l = list(map(int,input().split()))
index = {1:[],2:[],3:[]}
for i in range(n):
index[l[i]].append(i)
if len(index[1]) == 0 or len(index[2]) == 0 or len(index[3]) == 0:
print(0)
else :
res = dict(sorted(res.items(),key = lambda x:x[1]))
y = list(res.values())[0]
print(y)
ans = []
for i in range(y) :
print(* [index[1][i]+1,index[2][i]+1,index[3][i]+1] )
#print(index, res)
|
Title: Team Olympiad
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The School №0 of the capital of Berland has *n* children studying in it. All the children in this school are gifted: some of them are good at programming, some are good at maths, others are good at PE (Physical Education). Hence, for each child we know value *t**i*:
- *t**i*<==<=1, if the *i*-th child is good at programming, - *t**i*<==<=2, if the *i*-th child is good at maths, - *t**i*<==<=3, if the *i*-th child is good at PE
Each child happens to be good at exactly one of these three subjects.
The Team Scientific Decathlon Olympias requires teams of three students. The school teachers decided that the teams will be composed of three children that are good at different subjects. That is, each team must have one mathematician, one programmer and one sportsman. Of course, each child can be a member of no more than one team.
What is the maximum number of teams that the school will be able to present at the Olympiad? How should the teams be formed for that?
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=5000) — the number of children in the school. The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t**i*<=≤<=3), where *t**i* describes the skill of the *i*-th child.
Output Specification:
In the first line output integer *w* — the largest possible number of teams.
Then print *w* lines, containing three numbers in each line. Each triple represents the indexes of the children forming the team. You can print both the teams, and the numbers in the triplets in any order. The children are numbered from 1 to *n* in the order of their appearance in the input. Each child must participate in no more than one team. If there are several solutions, print any of them.
If no teams can be compiled, print the only line with value *w* equal to 0.
Demo Input:
['7\n1 3 1 3 2 1 2\n', '4\n2 1 1 2\n']
Demo Output:
['2\n3 5 2\n6 7 4\n', '0\n']
Note:
none
|
```python
n = int(input())
l = list(map(int,input().split()))
index = {1:[],2:[],3:[]}
for i in range(n):
index[l[i]].append(i)
if len(index[1]) == 0 or len(index[2]) == 0 or len(index[3]) == 0:
print(0)
else :
res = dict(sorted(res.items(),key = lambda x:x[1]))
y = list(res.values())[0]
print(y)
ans = []
for i in range(y) :
print(* [index[1][i]+1,index[2][i]+1,index[3][i]+1] )
#print(index, res)
```
| -1
|
|
573
|
A
|
Bear and Poker
|
PROGRAMMING
| 1,300
|
[
"implementation",
"math",
"number theory"
] | null | null |
Limak is an old brown bear. He often plays poker with his friends. Today they went to a casino. There are *n* players (including Limak himself) and right now all of them have bids on the table. *i*-th of them has bid with size *a**i* dollars.
Each player can double his bid any number of times and triple his bid any number of times. The casino has a great jackpot for making all bids equal. Is it possible that Limak and his friends will win a jackpot?
|
First line of input contains an integer *n* (2<=≤<=*n*<=≤<=105), the number of players.
The second line contains *n* integer numbers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109) — the bids of players.
|
Print "Yes" (without the quotes) if players can make their bids become equal, or "No" otherwise.
|
[
"4\n75 150 75 50\n",
"3\n100 150 250\n"
] |
[
"Yes\n",
"No\n"
] |
In the first sample test first and third players should double their bids twice, second player should double his bid once and fourth player should both double and triple his bid.
It can be shown that in the second sample test there is no way to make all bids equal.
| 500
|
[
{
"input": "4\n75 150 75 50",
"output": "Yes"
},
{
"input": "3\n100 150 250",
"output": "No"
},
{
"input": "7\n34 34 68 34 34 68 34",
"output": "Yes"
},
{
"input": "10\n72 96 12 18 81 20 6 2 54 1",
"output": "No"
},
{
"input": "20\n958692492 954966768 77387000 724664764 101294996 614007760 202904092 555293973 707655552 108023967 73123445 612562357 552908390 914853758 915004122 466129205 122853497 814592742 373389439 818473058",
"output": "No"
},
{
"input": "2\n1 1",
"output": "Yes"
},
{
"input": "2\n72 72",
"output": "Yes"
},
{
"input": "2\n49 42",
"output": "No"
},
{
"input": "3\n1000000000 1000000000 1000000000",
"output": "Yes"
},
{
"input": "6\n162000 96000 648000 1000 864000 432000",
"output": "Yes"
},
{
"input": "8\n600000 100000 100000 100000 900000 600000 900000 600000",
"output": "Yes"
},
{
"input": "12\n2048 1024 6144 1024 3072 3072 6144 1024 4096 2048 6144 3072",
"output": "Yes"
},
{
"input": "20\n246 246 246 246 246 246 246 246 246 246 246 246 246 246 246 246 246 246 246 246",
"output": "Yes"
},
{
"input": "50\n840868705 387420489 387420489 795385082 634350497 206851546 536870912 536870912 414927754 387420489 387420489 536870912 387420489 149011306 373106005 536870912 700746206 387420489 777952883 847215247 176645254 576664386 387420489 230876513 536870912 536870912 536870912 387420489 387420489 536870912 460495524 528643722 387420489 536870912 470369206 899619085 387420489 631148352 387420489 387420489 536870912 414666674 521349938 776784669 387420489 102428009 536870912 387420489 536870912 718311009",
"output": "No"
},
{
"input": "2\n5 6",
"output": "No"
},
{
"input": "3\n536870912 387420489 257407169",
"output": "No"
},
{
"input": "4\n2 2 5 2",
"output": "No"
},
{
"input": "2\n33554432 59049",
"output": "Yes"
},
{
"input": "3\n536870912 387420489 387420489",
"output": "Yes"
},
{
"input": "2\n1 5",
"output": "No"
},
{
"input": "18\n2 3 5 7 11 13 17 19 23 29 31 37 43 47 53 59 67 71",
"output": "No"
},
{
"input": "2\n1 30",
"output": "No"
},
{
"input": "3\n335544320 71744535 71744535",
"output": "Yes"
},
{
"input": "5\n1000000000 999999999 999999998 999999997 999999996",
"output": "No"
},
{
"input": "2\n25 5",
"output": "No"
},
{
"input": "4\n75 150 75 5",
"output": "No"
},
{
"input": "3\n536870912 387420489 362797056",
"output": "Yes"
},
{
"input": "3\n536870912 387420489 89",
"output": "No"
},
{
"input": "4\n547 2606459 222763549 143466789",
"output": "No"
},
{
"input": "3\n129140163 33554432 1",
"output": "Yes"
},
{
"input": "10\n244140625 244140625 244140625 244140625 244140625 244140625 244140625 244140625 536870912 387420489",
"output": "No"
},
{
"input": "3\n5 5 1",
"output": "No"
},
{
"input": "5\n3 7 29 36760123 823996703",
"output": "No"
}
] | 1,695,116,497
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 30
| 0
|
import math
def can_win_jackpot(bids):
# Calculate the GCD of all bid amounts
gcd = bids[0]
for bid in bids[1:]:
gcd = math.gcd(gcd, bid)
# Check if all bids can be made equal
for bid in bids:
if bid // gcd % 2 != 0 and bid // gcd % 3 != 0:
return "No"
return "Yes"
# Input
n = int(input())
bids = list(map(int, input().split()))
# Output
print(can_win_jackpot(bids))
|
Title: Bear and Poker
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Limak is an old brown bear. He often plays poker with his friends. Today they went to a casino. There are *n* players (including Limak himself) and right now all of them have bids on the table. *i*-th of them has bid with size *a**i* dollars.
Each player can double his bid any number of times and triple his bid any number of times. The casino has a great jackpot for making all bids equal. Is it possible that Limak and his friends will win a jackpot?
Input Specification:
First line of input contains an integer *n* (2<=≤<=*n*<=≤<=105), the number of players.
The second line contains *n* integer numbers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109) — the bids of players.
Output Specification:
Print "Yes" (without the quotes) if players can make their bids become equal, or "No" otherwise.
Demo Input:
['4\n75 150 75 50\n', '3\n100 150 250\n']
Demo Output:
['Yes\n', 'No\n']
Note:
In the first sample test first and third players should double their bids twice, second player should double his bid once and fourth player should both double and triple his bid.
It can be shown that in the second sample test there is no way to make all bids equal.
|
```python
import math
def can_win_jackpot(bids):
# Calculate the GCD of all bid amounts
gcd = bids[0]
for bid in bids[1:]:
gcd = math.gcd(gcd, bid)
# Check if all bids can be made equal
for bid in bids:
if bid // gcd % 2 != 0 and bid // gcd % 3 != 0:
return "No"
return "Yes"
# Input
n = int(input())
bids = list(map(int, input().split()))
# Output
print(can_win_jackpot(bids))
```
| 0
|
|
133
|
A
|
HQ9+
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
HQ9+ is a joke programming language which has only four one-character instructions:
- "H" prints "Hello, World!",- "Q" prints the source code of the program itself,- "9" prints the lyrics of "99 Bottles of Beer" song, - "+" increments the value stored in the internal accumulator.
Instructions "H" and "Q" are case-sensitive and must be uppercase. The characters of the program which are not instructions are ignored.
You are given a program written in HQ9+. You have to figure out whether executing this program will produce any output.
|
The input will consist of a single line *p* which will give a program in HQ9+. String *p* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *p* will be between 33 (exclamation mark) and 126 (tilde), inclusive.
|
Output "YES", if executing the program will produce any output, and "NO" otherwise.
|
[
"Hi!\n",
"Codeforces\n"
] |
[
"YES\n",
"NO\n"
] |
In the first case the program contains only one instruction — "H", which prints "Hello, World!".
In the second case none of the program characters are language instructions.
| 500
|
[
{
"input": "Hi!",
"output": "YES"
},
{
"input": "Codeforces",
"output": "NO"
},
{
"input": "a+b=c",
"output": "NO"
},
{
"input": "hq-lowercase",
"output": "NO"
},
{
"input": "Q",
"output": "YES"
},
{
"input": "9",
"output": "YES"
},
{
"input": "H",
"output": "YES"
},
{
"input": "+",
"output": "NO"
},
{
"input": "~",
"output": "NO"
},
{
"input": "dEHsbM'gS[\\brZ_dpjXw8f?L[4E\"s4Zc9*(,j:>p$}m7HD[_9nOWQ\\uvq2mHWR",
"output": "YES"
},
{
"input": "tt6l=RHOfStm.;Qd$-}zDes*E,.F7qn5-b%HC",
"output": "YES"
},
{
"input": "@F%K2=%RyL/",
"output": "NO"
},
{
"input": "juq)k(FT.^G=G\\zcqnO\"uJIE1_]KFH9S=1c\"mJ;F9F)%>&.WOdp09+k`Yc6}\"6xw,Aos:M\\_^^:xBb[CcsHm?J",
"output": "YES"
},
{
"input": "6G_\"Fq#<AWyHG=Rci1t%#Jc#x<Fpg'N@t%F=``YO7\\Zd;6PkMe<#91YgzTC)",
"output": "YES"
},
{
"input": "Fvg_~wC>SO4lF}*c`Q;mII9E{4.QodbqN]C",
"output": "YES"
},
{
"input": "p-UXsbd&f",
"output": "NO"
},
{
"input": "<]D7NMA)yZe=`?RbP5lsa.l_Mg^V:\"-0x+$3c,q&L%18Ku<HcA\\s!^OQblk^x{35S'>yz8cKgVHWZ]kV0>_",
"output": "YES"
},
{
"input": "f.20)8b+.R}Gy!DbHU3v(.(=Q^`z[_BaQ}eO=C1IK;b2GkD\\{\\Bf\"!#qh]",
"output": "YES"
},
{
"input": "}do5RU<(w<q[\"-NR)IAH_HyiD{",
"output": "YES"
},
{
"input": "Iy^.,Aw*,5+f;l@Q;jLK'G5H-r1Pfmx?ei~`CjMmUe{K:lS9cu4ay8rqRh-W?Gqv!e-j*U)!Mzn{E8B6%~aSZ~iQ_QwlC9_cX(o8",
"output": "YES"
},
{
"input": "sKLje,:q>-D,;NvQ3,qN3-N&tPx0nL/,>Ca|z\"k2S{NF7btLa3_TyXG4XZ:`(t&\"'^M|@qObZxv",
"output": "YES"
},
{
"input": "%z:c@1ZsQ@\\6U/NQ+M9R>,$bwG`U1+C\\18^:S},;kw!&4r|z`",
"output": "YES"
},
{
"input": "OKBB5z7ud81[Tn@P\"nDUd,>@",
"output": "NO"
},
{
"input": "y{0;neX]w0IenPvPx0iXp+X|IzLZZaRzBJ>q~LhMhD$x-^GDwl;,a'<bAqH8QrFwbK@oi?I'W.bZ]MlIQ/x(0YzbTH^l.)]0Bv",
"output": "YES"
},
{
"input": "EL|xIP5_+Caon1hPpQ0[8+r@LX4;b?gMy>;/WH)pf@Ur*TiXu*e}b-*%acUA~A?>MDz#!\\Uh",
"output": "YES"
},
{
"input": "UbkW=UVb>;z6)p@Phr;^Dn.|5O{_i||:Rv|KJ_ay~V(S&Jp",
"output": "NO"
},
{
"input": "!3YPv@2JQ44@)R2O_4`GO",
"output": "YES"
},
{
"input": "Kba/Q,SL~FMd)3hOWU'Jum{9\"$Ld4:GW}D]%tr@G{hpG:PV5-c'VIZ~m/6|3I?_4*1luKnOp`%p|0H{[|Y1A~4-ZdX,Rw2[\\",
"output": "YES"
},
{
"input": "NRN*=v>;oU7[acMIJn*n^bWm!cm3#E7Efr>{g-8bl\"DN4~_=f?[T;~Fq#&)aXq%</GcTJD^e$@Extm[e\"C)q_L",
"output": "NO"
},
{
"input": "y#<fv{_=$MP!{D%I\\1OqjaqKh[pqE$KvYL<9@*V'j8uH0/gQdA'G;&y4Cv6&",
"output": "YES"
},
{
"input": "+SE_Pg<?7Fh,z&uITQut2a-mk8X8La`c2A}",
"output": "YES"
},
{
"input": "Uh3>ER](J",
"output": "NO"
},
{
"input": "!:!{~=9*\\P;Z6F?HC5GadFz)>k*=u|+\"Cm]ICTmB!`L{&oS/z6b~#Snbp/^\\Q>XWU-vY+/dP.7S=-#&whS@,",
"output": "YES"
},
{
"input": "KimtYBZp+ISeO(uH;UldoE6eAcp|9u?SzGZd6j-e}[}u#e[Cx8.qgY]$2!",
"output": "YES"
},
{
"input": "[:[SN-{r>[l+OggH3v3g{EPC*@YBATT@",
"output": "YES"
},
{
"input": "'jdL(vX",
"output": "NO"
},
{
"input": "Q;R+aay]cL?Zh*uG\"YcmO*@Dts*Gjp}D~M7Z96+<4?9I3aH~0qNdO(RmyRy=ci,s8qD_kwj;QHFzD|5,5",
"output": "YES"
},
{
"input": "{Q@#<LU_v^qdh%gGxz*pu)Y\"]k-l-N30WAxvp2IE3:jD0Wi4H/xWPH&s",
"output": "YES"
},
{
"input": "~@Gb(S&N$mBuBUMAky-z^{5VwLNTzYg|ZUZncL@ahS?K*As<$iNUARM3r43J'jJB)$ujfPAq\"G<S9flGyakZg!2Z.-NJ|2{F>]",
"output": "YES"
},
{
"input": "Jp5Aa>aP6fZ!\\6%A}<S}j{O4`C6y$8|i3IW,WHy&\"ioE&7zP\"'xHAY;:x%@SnS]Mr{R|})gU",
"output": "YES"
},
{
"input": "ZA#:U)$RI^sE\\vuAt]x\"2zipI!}YEu2<j$:H0_9/~eB?#->",
"output": "YES"
},
{
"input": "&ppw0._:\\p-PuWM@l}%%=",
"output": "NO"
},
{
"input": "P(^pix\"=oiEZu8?@d@J(I`Xp5TN^T3\\Z7P5\"ZrvZ{2Fwz3g-8`U!)(1$a<g+9Q|COhDoH;HwFY02Pa|ZGp$/WZBR=>6Jg!yr",
"output": "YES"
},
{
"input": "`WfODc\\?#ax~1xu@[ao+o_rN|L7%v,p,nDv>3+6cy.]q3)+A6b!q*Hc+#.t4f~vhUa~$^q",
"output": "YES"
},
{
"input": ",)TH9N}'6t2+0Yg?S#6/{_.,!)9d}h'wG|sY&'Ul4D0l0",
"output": "YES"
},
{
"input": "VXB&r9Z)IlKOJ:??KDA",
"output": "YES"
},
{
"input": "\")1cL>{o\\dcYJzu?CefyN^bGRviOH&P7rJS3PT4:0V3F)%\\}L=AJouYsj_>j2|7^1NWu*%NbOP>ngv-ls<;b-4Sd3Na0R",
"output": "YES"
},
{
"input": "2Y}\\A)>row{~c[g>:'.|ZC8%UTQ/jcdhK%6O)QRC.kd@%y}LJYk=V{G5pQK/yKJ%{G3C",
"output": "YES"
},
{
"input": "O.&=qt(`z(",
"output": "NO"
},
{
"input": "_^r6fyIc/~~;>l%9?aVEi7-{=,[<aMiB'-scSg$$|\"jAzY0N>QkHHGBZj2c\"=fhRlWd5;5K|GgU?7h]!;wl@",
"output": "YES"
},
{
"input": "+/`sAd&eB29E=Nu87${.u6GY@$^a$,}s^!p!F}B-z8<<wORb<S7;HM1a,gp",
"output": "YES"
},
{
"input": "U_ilyOGMT+QiW/M8/D(1=6a7)_FA,h4`8",
"output": "YES"
},
{
"input": "!0WKT:$O",
"output": "NO"
},
{
"input": "1EE*I%EQz6$~pPu7|(r7nyPQt4uGU@]~H'4uII?b1_Wn)K?ZRHrr0z&Kr;}aO3<mN=3:{}QgPxI|Ncm4#)",
"output": "YES"
},
{
"input": "[u3\"$+!:/.<Dp1M7tH}:zxjt],^kv}qP;y12\"`^'/u*h%AFmPJ>e1#Yly",
"output": "YES"
},
{
"input": "'F!_]tB<A&UO+p?7liE>(x&RFgG2~\\(",
"output": "NO"
},
{
"input": "Qv)X8",
"output": "YES"
},
{
"input": "aGv7,J@&g1(}E3g6[LuDZwZl2<v7IwQA%\"R(?ouBD>_=y\"3Kf%^>vON<a^T\\G^ootgE@whWmZo=[ex|F",
"output": "YES"
},
{
"input": "e{}2vQ+/r@p0}cLKNe4MCk",
"output": "YES"
},
{
"input": "mzbmweyydiadtlcouegmdbyfwurpwbpuvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnkH",
"output": "YES"
},
{
"input": "Qzbmweyydiadtlcouegmdbyfwurpwbpuvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnky",
"output": "YES"
},
{
"input": "mzbmweyydiadtlcouegmdbyfwurpwb9uvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnky",
"output": "YES"
},
{
"input": "1H1",
"output": "YES"
},
{
"input": "+Q",
"output": "YES"
},
{
"input": "1ab",
"output": "NO"
},
{
"input": "!",
"output": "NO"
},
{
"input": "0+",
"output": "NO"
},
{
"input": "+H",
"output": "YES"
},
{
"input": "cH",
"output": "YES"
},
{
"input": "+8",
"output": "NO"
},
{
"input": "8+",
"output": "NO"
},
{
"input": "++++++++++++++++++++++++++",
"output": "NO"
},
{
"input": "(+)",
"output": "NO"
},
{
"input": "H+",
"output": "YES"
},
{
"input": "a!",
"output": "NO"
},
{
"input": "++++++++++++++",
"output": "NO"
},
{
"input": "+++++++++++++++++++++++++++++++++++++++++++++++++++++++++",
"output": "NO"
},
{
"input": "8",
"output": "NO"
},
{
"input": "3",
"output": "NO"
},
{
"input": "HQ9",
"output": "YES"
},
{
"input": "+++H",
"output": "YES"
},
{
"input": "++++++++++",
"output": "NO"
},
{
"input": "HHHHHHH",
"output": "YES"
},
{
"input": "abacabaH",
"output": "YES"
},
{
"input": "+G",
"output": "NO"
}
] | 1,690,259,616
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 85
| 124
| 0
|
def check(string):
for t in string:
if t in "HQ9":
return "YES"
return "NO"
string = input()
print(check(string))
|
Title: HQ9+
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
HQ9+ is a joke programming language which has only four one-character instructions:
- "H" prints "Hello, World!",- "Q" prints the source code of the program itself,- "9" prints the lyrics of "99 Bottles of Beer" song, - "+" increments the value stored in the internal accumulator.
Instructions "H" and "Q" are case-sensitive and must be uppercase. The characters of the program which are not instructions are ignored.
You are given a program written in HQ9+. You have to figure out whether executing this program will produce any output.
Input Specification:
The input will consist of a single line *p* which will give a program in HQ9+. String *p* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *p* will be between 33 (exclamation mark) and 126 (tilde), inclusive.
Output Specification:
Output "YES", if executing the program will produce any output, and "NO" otherwise.
Demo Input:
['Hi!\n', 'Codeforces\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In the first case the program contains only one instruction — "H", which prints "Hello, World!".
In the second case none of the program characters are language instructions.
|
```python
def check(string):
for t in string:
if t in "HQ9":
return "YES"
return "NO"
string = input()
print(check(string))
```
| 3
|
|
285
|
C
|
Building Permutation
|
PROGRAMMING
| 1,200
|
[
"greedy",
"implementation",
"sortings"
] | null | null |
Permutation *p* is an ordered set of integers *p*1,<=<=*p*2,<=<=...,<=<=*p**n*, consisting of *n* distinct positive integers, each of them doesn't exceed *n*. We'll denote the *i*-th element of permutation *p* as *p**i*. We'll call number *n* the size or the length of permutation *p*1,<=<=*p*2,<=<=...,<=<=*p**n*.
You have a sequence of integers *a*1,<=*a*2,<=...,<=*a**n*. In one move, you are allowed to decrease or increase any number by one. Count the minimum number of moves, needed to build a permutation from this sequence.
|
The first line contains integer *n* (1<=≤<=*n*<=≤<=3·105) — the size of the sought permutation. The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (<=-<=109<=≤<=*a**i*<=≤<=109).
|
Print a single number — the minimum number of moves.
Please, do not use the %lld specifier to read or write 64-bit integers in C++. It is preferred to use the cin, cout streams or the %I64d specifier.
|
[
"2\n3 0\n",
"3\n-1 -1 2\n"
] |
[
"2\n",
"6\n"
] |
In the first sample you should decrease the first number by one and then increase the second number by one. The resulting permutation is (2, 1).
In the second sample you need 6 moves to build permutation (1, 3, 2).
| 1,500
|
[
{
"input": "2\n3 0",
"output": "2"
},
{
"input": "3\n-1 -1 2",
"output": "6"
},
{
"input": "5\n-3 5 -3 3 3",
"output": "10"
},
{
"input": "10\n9 6 -2 4 1 1 1 9 6 2",
"output": "18"
},
{
"input": "9\n2 0 0 6 5 4 1 9 3",
"output": "15"
},
{
"input": "100\n-77 57 -95 -23 53 -28 82 -83 38 -73 85 28 25 6 -43 4 -10 -30 -9 -92 14 34 -93 61 36 -100 90 -68 28 16 100 -3 97 30 36 -55 62 -62 53 74 -50 -23 67 11 22 -30 -19 83 7 84 43 90 -65 -75 -15 97 90 15 66 2 13 -91 91 -44 46 51 51 -58 95 77 20 30 76 79 91 60 76 2 82 42 -93 94 -57 88 65 -95 -66 100 -9 33 -67 54 -99 97 53 13 54 66 60 -48",
"output": "3459"
}
] | 1,414,220,722
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 33
| 1,090
| 24,780,800
|
import sys
import math
n = int(sys.stdin.readline())
a = [int(x) for x in (sys.stdin.readline()).split()]
a.sort()
res = 0
for i in range(n):
res += int(math.fabs(i + 1 - a[i]))
print(res)
|
Title: Building Permutation
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Permutation *p* is an ordered set of integers *p*1,<=<=*p*2,<=<=...,<=<=*p**n*, consisting of *n* distinct positive integers, each of them doesn't exceed *n*. We'll denote the *i*-th element of permutation *p* as *p**i*. We'll call number *n* the size or the length of permutation *p*1,<=<=*p*2,<=<=...,<=<=*p**n*.
You have a sequence of integers *a*1,<=*a*2,<=...,<=*a**n*. In one move, you are allowed to decrease or increase any number by one. Count the minimum number of moves, needed to build a permutation from this sequence.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=3·105) — the size of the sought permutation. The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (<=-<=109<=≤<=*a**i*<=≤<=109).
Output Specification:
Print a single number — the minimum number of moves.
Please, do not use the %lld specifier to read or write 64-bit integers in C++. It is preferred to use the cin, cout streams or the %I64d specifier.
Demo Input:
['2\n3 0\n', '3\n-1 -1 2\n']
Demo Output:
['2\n', '6\n']
Note:
In the first sample you should decrease the first number by one and then increase the second number by one. The resulting permutation is (2, 1).
In the second sample you need 6 moves to build permutation (1, 3, 2).
|
```python
import sys
import math
n = int(sys.stdin.readline())
a = [int(x) for x in (sys.stdin.readline()).split()]
a.sort()
res = 0
for i in range(n):
res += int(math.fabs(i + 1 - a[i]))
print(res)
```
| 3
|
|
342
|
A
|
Xenia and Divisors
|
PROGRAMMING
| 1,200
|
[
"greedy",
"implementation"
] | null | null |
Xenia the mathematician has a sequence consisting of *n* (*n* is divisible by 3) positive integers, each of them is at most 7. She wants to split the sequence into groups of three so that for each group of three *a*,<=*b*,<=*c* the following conditions held:
- *a*<=<<=*b*<=<<=*c*; - *a* divides *b*, *b* divides *c*.
Naturally, Xenia wants each element of the sequence to belong to exactly one group of three. Thus, if the required partition exists, then it has groups of three.
Help Xenia, find the required partition or else say that it doesn't exist.
|
The first line contains integer *n* (3<=≤<=*n*<=≤<=99999) — the number of elements in the sequence. The next line contains *n* positive integers, each of them is at most 7.
It is guaranteed that *n* is divisible by 3.
|
If the required partition exists, print groups of three. Print each group as values of the elements it contains. You should print values in increasing order. Separate the groups and integers in groups by whitespaces. If there are multiple solutions, you can print any of them.
If there is no solution, print -1.
|
[
"6\n1 1 1 2 2 2\n",
"6\n2 2 1 1 4 6\n"
] |
[
"-1\n",
"1 2 4\n1 2 6\n"
] |
none
| 500
|
[
{
"input": "6\n1 1 1 2 2 2",
"output": "-1"
},
{
"input": "6\n2 2 1 1 4 6",
"output": "1 2 4\n1 2 6"
},
{
"input": "3\n1 2 3",
"output": "-1"
},
{
"input": "3\n7 5 7",
"output": "-1"
},
{
"input": "3\n1 3 4",
"output": "-1"
},
{
"input": "3\n1 1 1",
"output": "-1"
},
{
"input": "9\n1 3 6 6 3 1 3 1 6",
"output": "1 3 6\n1 3 6\n1 3 6"
},
{
"input": "6\n1 2 4 1 3 5",
"output": "-1"
},
{
"input": "3\n1 3 7",
"output": "-1"
},
{
"input": "3\n1 1 1",
"output": "-1"
},
{
"input": "9\n1 2 4 1 2 4 1 3 6",
"output": "1 2 4\n1 2 4\n1 3 6"
},
{
"input": "12\n3 6 1 1 3 6 1 1 2 6 2 6",
"output": "1 3 6\n1 3 6\n1 2 6\n1 2 6"
},
{
"input": "9\n1 1 1 4 4 4 6 2 2",
"output": "-1"
},
{
"input": "9\n1 2 4 6 3 1 3 1 5",
"output": "-1"
},
{
"input": "15\n2 1 2 1 3 6 1 2 1 6 1 3 4 6 4",
"output": "1 2 4\n1 2 4\n1 3 6\n1 3 6\n1 2 6"
},
{
"input": "3\n2 3 6",
"output": "-1"
},
{
"input": "3\n2 4 6",
"output": "-1"
},
{
"input": "3\n2 5 6",
"output": "-1"
},
{
"input": "3\n2 4 7",
"output": "-1"
},
{
"input": "6\n1 2 3 4 5 6",
"output": "-1"
},
{
"input": "3\n7 7 7",
"output": "-1"
},
{
"input": "6\n1 2 4 7 7 7",
"output": "-1"
},
{
"input": "6\n1 1 2 6 6 6",
"output": "-1"
},
{
"input": "9\n1 1 1 3 3 2 4 4 6",
"output": "-1"
},
{
"input": "6\n1 2 4 5 5 5",
"output": "-1"
},
{
"input": "15\n1 1 1 1 1 2 2 2 2 4 4 6 6 6 6",
"output": "-1"
},
{
"input": "6\n1 1 5 5 7 7",
"output": "-1"
},
{
"input": "9\n1 1 1 2 3 4 5 6 7",
"output": "-1"
},
{
"input": "6\n1 1 4 4 7 7",
"output": "-1"
},
{
"input": "24\n1 1 1 1 1 1 1 1 1 2 2 2 3 3 3 3 3 3 4 4 4 6 6 6",
"output": "-1"
},
{
"input": "3\n1 7 6",
"output": "-1"
},
{
"input": "6\n1 1 2 4 7 7",
"output": "-1"
},
{
"input": "9\n1 1 1 7 7 7 7 7 7",
"output": "-1"
},
{
"input": "9\n1 1 1 2 3 4 6 5 5",
"output": "-1"
}
] | 1,615,668,940
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 45
| 280
| 2,662,400
|
import collections as coll
groups,impossible = [],False
n,nums = int(input()), coll.Counter(map(int,input().split(" ")))
x = n // 3
for x in range(x):
group = []
if nums[1] != 0:
group.append(1)
nums[1] -= 1
else:
impossible = True
break
if nums[2] != 0:
group.append(2)
nums[2] -= 1
if nums[4] != 0:
group.append(4)
nums[4] -= 1
elif nums[6] != 0:
group.append(6)
nums[6] -= 1
else:
impossible = True
break
elif nums[3] != 0 and nums[6] != 0:
group.append(3)
group.append(6)
nums[3] -= 1
nums[6] -= 1
else:
impossible = True
break
groups.append(group)
if impossible: print(-1)
else:
for group in groups:
print(*group)
'''
the numbers which we get on the input
should be at most 7. It means that if we have at least one 7 or 5
on our input, it is impossible to create a required partition since
7 and 5 are primes. And they are not divisors because max is 7, and numbers cannot
be the same in one group.
a < b < c. (without this condition something like that could exists 1,1,7, 5,5,5)
a | b && b | c
If 'n' is always divisible by 3. It means that we have to use every signle number.
6,4,3,2,1 (valid divisors: 3,2,1)
Since numbers are at most 7, we have very limited amount of groups which are vaild for these
conditions: (Every group should start from 4 or 6, otherwise it's impossible to satisfy parititon)
1,2,4
1,2,6
1,3,6
wystarczy sprawdzic ilosc liczb
suma ilosci czworek i szostek musi dac liczbe grup poniewaz wszystkie musza
sie konczyc na 6 albo 4. Liczba jedynek musi byc tyle samo co grup.
Oraz liczba 2 i 3:
odkad wszystkie musza sie zaczynac na 1 biorac pod uwage warunki.
I mozna pojsc od jedynek w takim razie przy konstrukcji,
jezeli do niej dojdziemy tzn ze mozemy stworzyc te grupy
1 - 2 - 4
1 - 2 - 6
1 - 3 - 6
Jezeli w grupie bedzie jakas 5,7 albo za duzo czegos lub za malo tzn ze niemozliwe
spelnienie warunkow.
'''
|
Title: Xenia and Divisors
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Xenia the mathematician has a sequence consisting of *n* (*n* is divisible by 3) positive integers, each of them is at most 7. She wants to split the sequence into groups of three so that for each group of three *a*,<=*b*,<=*c* the following conditions held:
- *a*<=<<=*b*<=<<=*c*; - *a* divides *b*, *b* divides *c*.
Naturally, Xenia wants each element of the sequence to belong to exactly one group of three. Thus, if the required partition exists, then it has groups of three.
Help Xenia, find the required partition or else say that it doesn't exist.
Input Specification:
The first line contains integer *n* (3<=≤<=*n*<=≤<=99999) — the number of elements in the sequence. The next line contains *n* positive integers, each of them is at most 7.
It is guaranteed that *n* is divisible by 3.
Output Specification:
If the required partition exists, print groups of three. Print each group as values of the elements it contains. You should print values in increasing order. Separate the groups and integers in groups by whitespaces. If there are multiple solutions, you can print any of them.
If there is no solution, print -1.
Demo Input:
['6\n1 1 1 2 2 2\n', '6\n2 2 1 1 4 6\n']
Demo Output:
['-1\n', '1 2 4\n1 2 6\n']
Note:
none
|
```python
import collections as coll
groups,impossible = [],False
n,nums = int(input()), coll.Counter(map(int,input().split(" ")))
x = n // 3
for x in range(x):
group = []
if nums[1] != 0:
group.append(1)
nums[1] -= 1
else:
impossible = True
break
if nums[2] != 0:
group.append(2)
nums[2] -= 1
if nums[4] != 0:
group.append(4)
nums[4] -= 1
elif nums[6] != 0:
group.append(6)
nums[6] -= 1
else:
impossible = True
break
elif nums[3] != 0 and nums[6] != 0:
group.append(3)
group.append(6)
nums[3] -= 1
nums[6] -= 1
else:
impossible = True
break
groups.append(group)
if impossible: print(-1)
else:
for group in groups:
print(*group)
'''
the numbers which we get on the input
should be at most 7. It means that if we have at least one 7 or 5
on our input, it is impossible to create a required partition since
7 and 5 are primes. And they are not divisors because max is 7, and numbers cannot
be the same in one group.
a < b < c. (without this condition something like that could exists 1,1,7, 5,5,5)
a | b && b | c
If 'n' is always divisible by 3. It means that we have to use every signle number.
6,4,3,2,1 (valid divisors: 3,2,1)
Since numbers are at most 7, we have very limited amount of groups which are vaild for these
conditions: (Every group should start from 4 or 6, otherwise it's impossible to satisfy parititon)
1,2,4
1,2,6
1,3,6
wystarczy sprawdzic ilosc liczb
suma ilosci czworek i szostek musi dac liczbe grup poniewaz wszystkie musza
sie konczyc na 6 albo 4. Liczba jedynek musi byc tyle samo co grup.
Oraz liczba 2 i 3:
odkad wszystkie musza sie zaczynac na 1 biorac pod uwage warunki.
I mozna pojsc od jedynek w takim razie przy konstrukcji,
jezeli do niej dojdziemy tzn ze mozemy stworzyc te grupy
1 - 2 - 4
1 - 2 - 6
1 - 3 - 6
Jezeli w grupie bedzie jakas 5,7 albo za duzo czegos lub za malo tzn ze niemozliwe
spelnienie warunkow.
'''
```
| 3
|
|
835
|
C
|
Star sky
|
PROGRAMMING
| 1,600
|
[
"dp",
"implementation"
] | null | null |
The Cartesian coordinate system is set in the sky. There you can see *n* stars, the *i*-th has coordinates (*x**i*, *y**i*), a maximum brightness *c*, equal for all stars, and an initial brightness *s**i* (0<=≤<=*s**i*<=≤<=*c*).
Over time the stars twinkle. At moment 0 the *i*-th star has brightness *s**i*. Let at moment *t* some star has brightness *x*. Then at moment (*t*<=+<=1) this star will have brightness *x*<=+<=1, if *x*<=+<=1<=≤<=*c*, and 0, otherwise.
You want to look at the sky *q* times. In the *i*-th time you will look at the moment *t**i* and you will see a rectangle with sides parallel to the coordinate axes, the lower left corner has coordinates (*x*1*i*, *y*1*i*) and the upper right — (*x*2*i*, *y*2*i*). For each view, you want to know the total brightness of the stars lying in the viewed rectangle.
A star lies in a rectangle if it lies on its border or lies strictly inside it.
|
The first line contains three integers *n*, *q*, *c* (1<=≤<=*n*,<=*q*<=≤<=105, 1<=≤<=*c*<=≤<=10) — the number of the stars, the number of the views and the maximum brightness of the stars.
The next *n* lines contain the stars description. The *i*-th from these lines contains three integers *x**i*, *y**i*, *s**i* (1<=≤<=*x**i*,<=*y**i*<=≤<=100, 0<=≤<=*s**i*<=≤<=*c*<=≤<=10) — the coordinates of *i*-th star and its initial brightness.
The next *q* lines contain the views description. The *i*-th from these lines contains five integers *t**i*, *x*1*i*, *y*1*i*, *x*2*i*, *y*2*i* (0<=≤<=*t**i*<=≤<=109, 1<=≤<=*x*1*i*<=<<=*x*2*i*<=≤<=100, 1<=≤<=*y*1*i*<=<<=*y*2*i*<=≤<=100) — the moment of the *i*-th view and the coordinates of the viewed rectangle.
|
For each view print the total brightness of the viewed stars.
|
[
"2 3 3\n1 1 1\n3 2 0\n2 1 1 2 2\n0 2 1 4 5\n5 1 1 5 5\n",
"3 4 5\n1 1 2\n2 3 0\n3 3 1\n0 1 1 100 100\n1 2 2 4 4\n2 2 1 4 7\n1 50 50 51 51\n"
] |
[
"3\n0\n3\n",
"3\n3\n5\n0\n"
] |
Let's consider the first example.
At the first view, you can see only the first star. At moment 2 its brightness is 3, so the answer is 3.
At the second view, you can see only the second star. At moment 0 its brightness is 0, so the answer is 0.
At the third view, you can see both stars. At moment 5 brightness of the first is 2, and brightness of the second is 1, so the answer is 3.
| 1,250
|
[
{
"input": "2 3 3\n1 1 1\n3 2 0\n2 1 1 2 2\n0 2 1 4 5\n5 1 1 5 5",
"output": "3\n0\n3"
},
{
"input": "3 4 5\n1 1 2\n2 3 0\n3 3 1\n0 1 1 100 100\n1 2 2 4 4\n2 2 1 4 7\n1 50 50 51 51",
"output": "3\n3\n5\n0"
}
] | 1,599,560,593
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 52
| 1,996
| 5,120,000
|
import math,sys,bisect,heapq
from collections import defaultdict,Counter,deque
from itertools import groupby,accumulate
#sys.setrecursionlimit(200000000)
int1 = lambda x: int(x) - 1
#input = iter(sys.stdin.buffer.read().decode().splitlines()).__next__
ilele = lambda: map(int,input().split())
alele = lambda: list(map(int, input().split()))
ilelec = lambda: map(int1,input().split())
alelec = lambda: list(map(int1, input().split()))
def list2d(a, b, c): return [[c] * b for i in range(a)]
def list3d(a, b, c, d): return [[[d] * c for j in range(b)] for i in range(a)]
#MOD = 1000000000 + 7
def Y(c): print(["NO","YES"][c])
def y(c): print(["no","yes"][c])
def Yy(c): print(["No","Yes"][c])
dp = {}
def fun(A):
B = list2d(101,101,0)
for j in range(101):
B[0][j] = A[0][j]
for i in range(1,101):
for j in range(101):
B[i][j] = A[i][j] + B[i-1][j]
for i in range(101):
for j in range(1,101):
B[i][j] = B[i][j] + B[i][j-1]
return B
n,q,c = ilele()
G = defaultdict(list)
for i in range(n):
a,b,s = ilele()
G[(a,b)].append(s)
#print(G)
for i in range(c+1):
#print(i,c)
A = list2d(101,101,0)
for j in range(1,101):
for k in range(1,101):
x = G.get((j,k),[])
for l in x:
r = (l + i)%(c+1)
#print(j,k,r,l,i)
A[j][k] += r
B = fun(A)
dp[i] = B
for i in range(q):
t,x1,y1,x2,y2 = ilele()
t %= (c+1)
#print(dp[t][x2][y2],dp[t][x2][y1])
ans = dp[t][x2][y2]
ans -= dp[t][x2][y1-1]
ans -= dp[t][x1-1][y2]
ans += dp[t][x1-1][y1-1]
print(ans)
|
Title: Star sky
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The Cartesian coordinate system is set in the sky. There you can see *n* stars, the *i*-th has coordinates (*x**i*, *y**i*), a maximum brightness *c*, equal for all stars, and an initial brightness *s**i* (0<=≤<=*s**i*<=≤<=*c*).
Over time the stars twinkle. At moment 0 the *i*-th star has brightness *s**i*. Let at moment *t* some star has brightness *x*. Then at moment (*t*<=+<=1) this star will have brightness *x*<=+<=1, if *x*<=+<=1<=≤<=*c*, and 0, otherwise.
You want to look at the sky *q* times. In the *i*-th time you will look at the moment *t**i* and you will see a rectangle with sides parallel to the coordinate axes, the lower left corner has coordinates (*x*1*i*, *y*1*i*) and the upper right — (*x*2*i*, *y*2*i*). For each view, you want to know the total brightness of the stars lying in the viewed rectangle.
A star lies in a rectangle if it lies on its border or lies strictly inside it.
Input Specification:
The first line contains three integers *n*, *q*, *c* (1<=≤<=*n*,<=*q*<=≤<=105, 1<=≤<=*c*<=≤<=10) — the number of the stars, the number of the views and the maximum brightness of the stars.
The next *n* lines contain the stars description. The *i*-th from these lines contains three integers *x**i*, *y**i*, *s**i* (1<=≤<=*x**i*,<=*y**i*<=≤<=100, 0<=≤<=*s**i*<=≤<=*c*<=≤<=10) — the coordinates of *i*-th star and its initial brightness.
The next *q* lines contain the views description. The *i*-th from these lines contains five integers *t**i*, *x*1*i*, *y*1*i*, *x*2*i*, *y*2*i* (0<=≤<=*t**i*<=≤<=109, 1<=≤<=*x*1*i*<=<<=*x*2*i*<=≤<=100, 1<=≤<=*y*1*i*<=<<=*y*2*i*<=≤<=100) — the moment of the *i*-th view and the coordinates of the viewed rectangle.
Output Specification:
For each view print the total brightness of the viewed stars.
Demo Input:
['2 3 3\n1 1 1\n3 2 0\n2 1 1 2 2\n0 2 1 4 5\n5 1 1 5 5\n', '3 4 5\n1 1 2\n2 3 0\n3 3 1\n0 1 1 100 100\n1 2 2 4 4\n2 2 1 4 7\n1 50 50 51 51\n']
Demo Output:
['3\n0\n3\n', '3\n3\n5\n0\n']
Note:
Let's consider the first example.
At the first view, you can see only the first star. At moment 2 its brightness is 3, so the answer is 3.
At the second view, you can see only the second star. At moment 0 its brightness is 0, so the answer is 0.
At the third view, you can see both stars. At moment 5 brightness of the first is 2, and brightness of the second is 1, so the answer is 3.
|
```python
import math,sys,bisect,heapq
from collections import defaultdict,Counter,deque
from itertools import groupby,accumulate
#sys.setrecursionlimit(200000000)
int1 = lambda x: int(x) - 1
#input = iter(sys.stdin.buffer.read().decode().splitlines()).__next__
ilele = lambda: map(int,input().split())
alele = lambda: list(map(int, input().split()))
ilelec = lambda: map(int1,input().split())
alelec = lambda: list(map(int1, input().split()))
def list2d(a, b, c): return [[c] * b for i in range(a)]
def list3d(a, b, c, d): return [[[d] * c for j in range(b)] for i in range(a)]
#MOD = 1000000000 + 7
def Y(c): print(["NO","YES"][c])
def y(c): print(["no","yes"][c])
def Yy(c): print(["No","Yes"][c])
dp = {}
def fun(A):
B = list2d(101,101,0)
for j in range(101):
B[0][j] = A[0][j]
for i in range(1,101):
for j in range(101):
B[i][j] = A[i][j] + B[i-1][j]
for i in range(101):
for j in range(1,101):
B[i][j] = B[i][j] + B[i][j-1]
return B
n,q,c = ilele()
G = defaultdict(list)
for i in range(n):
a,b,s = ilele()
G[(a,b)].append(s)
#print(G)
for i in range(c+1):
#print(i,c)
A = list2d(101,101,0)
for j in range(1,101):
for k in range(1,101):
x = G.get((j,k),[])
for l in x:
r = (l + i)%(c+1)
#print(j,k,r,l,i)
A[j][k] += r
B = fun(A)
dp[i] = B
for i in range(q):
t,x1,y1,x2,y2 = ilele()
t %= (c+1)
#print(dp[t][x2][y2],dp[t][x2][y1])
ans = dp[t][x2][y2]
ans -= dp[t][x2][y1-1]
ans -= dp[t][x1-1][y2]
ans += dp[t][x1-1][y1-1]
print(ans)
```
| 3
|
|
935
|
C
|
Fifa and Fafa
|
PROGRAMMING
| 1,600
|
[
"geometry"
] | null | null |
Fifa and Fafa are sharing a flat. Fifa loves video games and wants to download a new soccer game. Unfortunately, Fafa heavily uses the internet which consumes the quota. Fifa can access the internet through his Wi-Fi access point. This access point can be accessed within a range of *r* meters (this range can be chosen by Fifa) from its position. Fifa must put the access point inside the flat which has a circular shape of radius *R*. Fifa wants to minimize the area that is not covered by the access point inside the flat without letting Fafa or anyone outside the flat to get access to the internet.
The world is represented as an infinite 2D plane. The flat is centered at (*x*1,<=*y*1) and has radius *R* and Fafa's laptop is located at (*x*2,<=*y*2), not necessarily inside the flat. Find the position and the radius chosen by Fifa for his access point which minimizes the uncovered area.
|
The single line of the input contains 5 space-separated integers *R*,<=*x*1,<=*y*1,<=*x*2,<=*y*2 (1<=≤<=*R*<=≤<=105, |*x*1|,<=|*y*1|,<=|*x*2|,<=|*y*2|<=≤<=105).
|
Print three space-separated numbers *x**ap*,<=*y**ap*,<=*r* where (*x**ap*,<=*y**ap*) is the position which Fifa chose for the access point and *r* is the radius of its range.
Your answer will be considered correct if the radius does not differ from optimal more than 10<=-<=6 absolutely or relatively, and also the radius you printed can be changed by no more than 10<=-<=6 (absolutely or relatively) in such a way that all points outside the flat and Fafa's laptop position are outside circle of the access point range.
|
[
"5 3 3 1 1\n",
"10 5 5 5 15\n"
] |
[
"3.7677669529663684 3.7677669529663684 3.914213562373095\n",
"5.0 5.0 10.0\n"
] |
none
| 1,250
|
[
{
"input": "5 3 3 1 1",
"output": "3.7677669529663684 3.7677669529663684 3.914213562373095"
},
{
"input": "10 5 5 5 15",
"output": "5.0 5.0 10.0"
},
{
"input": "5 0 0 0 7",
"output": "0 0 5"
},
{
"input": "10 0 0 0 0",
"output": "5.0 0.0 5.0"
},
{
"input": "100000 100000 100000 10000 10000",
"output": "100000 100000 100000"
},
{
"input": "100000 -100000 100000 -10000 100000",
"output": "-105000.0 100000.0 95000.0"
},
{
"input": "1 0 0 0 -1",
"output": "0.0 0.0 1.0"
},
{
"input": "100000 83094 84316 63590 53480",
"output": "100069.69149822203 111154.72144376408 68243.2515742123"
},
{
"input": "1 0 0 0 0",
"output": "0.5 0.0 0.5"
},
{
"input": "1 0 0 -2 -2",
"output": "0 0 1"
},
{
"input": "10 0 0 4 0",
"output": "-3.0 0.0 7.0"
},
{
"input": "82 1928 -30264 2004 -30294",
"output": "1927.8636359254158 -30263.946172075823 81.85339643163098"
},
{
"input": "75 -66998 89495 -66988 89506",
"output": "-67018.22522977486 89472.75224724766 44.933034373659254"
},
{
"input": "11 9899 34570 9895 34565",
"output": "9900.435822761548 34571.794778451935 8.701562118716424"
},
{
"input": "21 7298 -45672 7278 -45677",
"output": "7298.186496251526 -45671.95337593712 20.80776406404415"
},
{
"input": "31 84194 -71735 84170 -71758",
"output": "84194 -71735 31"
},
{
"input": "436 25094 -66597 25383 -66277",
"output": "25092.386577687754 -66598.78648837341 433.5927874489312"
},
{
"input": "390 -98011 78480 -98362 78671",
"output": "-98011 78480 390"
},
{
"input": "631 -21115 -1762 -21122 -1629",
"output": "-21101.91768814977 -2010.563925154407 382.0920415665416"
},
{
"input": "872 55782 51671 54965 51668",
"output": "55809.49706065544 51671.100968398976 844.502753968685"
},
{
"input": "519 -92641 -28571 -92540 -28203",
"output": "-92659.18165738975 -28637.246038806206 450.30421903092184"
},
{
"input": "3412 23894 22453 26265 25460",
"output": "23894 22453 3412"
},
{
"input": "3671 -99211 -3610 -99825 -1547",
"output": "-98994.40770099283 -4337.736014416596 2911.7161725229744"
},
{
"input": "3930 -76494 -83852 -78181 -81125",
"output": "-76303.71953677801 -84159.58436467478 3568.316718555632"
},
{
"input": "4189 -24915 61224 -28221 65024",
"output": "-24915 61224 4189"
},
{
"input": "8318 -2198 35161 3849 29911",
"output": "-2315.0277877457083 35262.60342081445 8163.0201360632545"
},
{
"input": "15096 -12439 58180 -10099 50671",
"output": "-13514.641370727473 61631.70557811649 11480.578066612283"
},
{
"input": "70343 64457 3256 83082 -17207",
"output": "50095.092392996106 19035.206193939368 49006.464709026186"
},
{
"input": "66440 -58647 -76987 2151 -40758",
"output": "-58647 -76987 66440"
},
{
"input": "62537 18249 96951 -3656 54754",
"output": "21702.922094423477 103604.5106422455 55040.41533091097"
},
{
"input": "88209 95145 42027 21960 26111",
"output": "101649.61478542663 43441.59928844504 81552.34132964142"
},
{
"input": "100000 -100000 -100000 -100000 -100000",
"output": "-50000.0 -100000.0 50000.0"
},
{
"input": "100000 100000 100000 100000 100000",
"output": "150000.0 100000.0 50000.0"
},
{
"input": "2 0 0 0 1",
"output": "0.0 -0.5 1.5"
},
{
"input": "1 1 0 1 0",
"output": "1.5 0.0 0.5"
},
{
"input": "2 3 3 3 3",
"output": "4.0 3.0 1.0"
},
{
"input": "1 1 1 1 1",
"output": "1.5 1.0 0.5"
},
{
"input": "10 1 1 1 1",
"output": "6.0 1.0 5.0"
},
{
"input": "10 5 5 5 10",
"output": "5.0 2.5 7.5"
},
{
"input": "5 0 0 0 0",
"output": "2.5 0.0 2.5"
}
] | 1,670,409,346
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 40
| 77
| 0
|
import sys
input = sys.stdin.readline
r, x1, y1, x2, y2 = map(int, input().split())
a = ((x2-x1)**2 + (y2-y1)**2)**0.5
if a >= r:
print(x1, y1, r)
else:
q = (a+r)/2
if a == 0:
u = x2 + q
v = y2
else:
u = x2 + (x1-x2)/a*q
v = y2 + (y1-y2)/a*q
print(u, v, q)
|
Title: Fifa and Fafa
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Fifa and Fafa are sharing a flat. Fifa loves video games and wants to download a new soccer game. Unfortunately, Fafa heavily uses the internet which consumes the quota. Fifa can access the internet through his Wi-Fi access point. This access point can be accessed within a range of *r* meters (this range can be chosen by Fifa) from its position. Fifa must put the access point inside the flat which has a circular shape of radius *R*. Fifa wants to minimize the area that is not covered by the access point inside the flat without letting Fafa or anyone outside the flat to get access to the internet.
The world is represented as an infinite 2D plane. The flat is centered at (*x*1,<=*y*1) and has radius *R* and Fafa's laptop is located at (*x*2,<=*y*2), not necessarily inside the flat. Find the position and the radius chosen by Fifa for his access point which minimizes the uncovered area.
Input Specification:
The single line of the input contains 5 space-separated integers *R*,<=*x*1,<=*y*1,<=*x*2,<=*y*2 (1<=≤<=*R*<=≤<=105, |*x*1|,<=|*y*1|,<=|*x*2|,<=|*y*2|<=≤<=105).
Output Specification:
Print three space-separated numbers *x**ap*,<=*y**ap*,<=*r* where (*x**ap*,<=*y**ap*) is the position which Fifa chose for the access point and *r* is the radius of its range.
Your answer will be considered correct if the radius does not differ from optimal more than 10<=-<=6 absolutely or relatively, and also the radius you printed can be changed by no more than 10<=-<=6 (absolutely or relatively) in such a way that all points outside the flat and Fafa's laptop position are outside circle of the access point range.
Demo Input:
['5 3 3 1 1\n', '10 5 5 5 15\n']
Demo Output:
['3.7677669529663684 3.7677669529663684 3.914213562373095\n', '5.0 5.0 10.0\n']
Note:
none
|
```python
import sys
input = sys.stdin.readline
r, x1, y1, x2, y2 = map(int, input().split())
a = ((x2-x1)**2 + (y2-y1)**2)**0.5
if a >= r:
print(x1, y1, r)
else:
q = (a+r)/2
if a == 0:
u = x2 + q
v = y2
else:
u = x2 + (x1-x2)/a*q
v = y2 + (y1-y2)/a*q
print(u, v, q)
```
| 3
|
|
709
|
A
|
Juicer
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
Kolya is going to make fresh orange juice. He has *n* oranges of sizes *a*1,<=*a*2,<=...,<=*a**n*. Kolya will put them in the juicer in the fixed order, starting with orange of size *a*1, then orange of size *a*2 and so on. To be put in the juicer the orange must have size not exceeding *b*, so if Kolya sees an orange that is strictly greater he throws it away and continues with the next one.
The juicer has a special section to collect waste. It overflows if Kolya squeezes oranges of the total size strictly greater than *d*. When it happens Kolya empties the waste section (even if there are no more oranges) and continues to squeeze the juice. How many times will he have to empty the waste section?
|
The first line of the input contains three integers *n*, *b* and *d* (1<=≤<=*n*<=≤<=100<=000, 1<=≤<=*b*<=≤<=*d*<=≤<=1<=000<=000) — the number of oranges, the maximum size of the orange that fits in the juicer and the value *d*, which determines the condition when the waste section should be emptied.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=1<=000<=000) — sizes of the oranges listed in the order Kolya is going to try to put them in the juicer.
|
Print one integer — the number of times Kolya will have to empty the waste section.
|
[
"2 7 10\n5 6\n",
"1 5 10\n7\n",
"3 10 10\n5 7 7\n",
"1 1 1\n1\n"
] |
[
"1\n",
"0\n",
"1\n",
"0\n"
] |
In the first sample, Kolya will squeeze the juice from two oranges and empty the waste section afterwards.
In the second sample, the orange won't fit in the juicer so Kolya will have no juice at all.
| 500
|
[
{
"input": "2 7 10\n5 6",
"output": "1"
},
{
"input": "1 5 10\n7",
"output": "0"
},
{
"input": "3 10 10\n5 7 7",
"output": "1"
},
{
"input": "1 1 1\n1",
"output": "0"
},
{
"input": "2 951637 951638\n44069 951637",
"output": "1"
},
{
"input": "50 100 129\n55 130 91 19 116 3 63 52 104 76 75 27 151 99 149 147 39 148 84 9 132 49 40 112 124 141 144 93 36 32 146 74 48 38 150 55 94 32 107 69 77 81 33 57 62 98 78 127 154 126",
"output": "12"
},
{
"input": "100 1000 1083\n992 616 818 359 609 783 263 989 501 929 362 394 919 1081 870 830 1097 975 62 346 531 367 323 457 707 360 949 334 867 116 478 417 961 963 1029 114 867 1008 988 916 983 1077 959 942 572 961 579 318 721 337 488 717 111 70 416 685 987 130 353 107 61 191 827 849 106 815 211 953 111 398 889 860 801 71 375 320 395 1059 116 222 931 444 582 74 677 655 88 173 686 491 661 186 114 832 615 814 791 464 517 850",
"output": "36"
},
{
"input": "2 6 8\n2 1",
"output": "0"
},
{
"input": "5 15 16\n7 11 5 12 8",
"output": "2"
},
{
"input": "15 759966 759967\n890397 182209 878577 548548 759966 812923 759966 860479 200595 381358 299175 339368 759966 907668 69574",
"output": "4"
},
{
"input": "5 234613 716125\n642626 494941 234613 234613 234613",
"output": "0"
},
{
"input": "50 48547 567054\n529808 597004 242355 559114 78865 537318 631455 733020 655072 645093 309010 855034 306058 625046 524574 834944 27330 664392 443637 821584 338013 490702 289520 675471 885846 258814 134220 571301 84875 94132 200425 928833 375166 521232 317961 175315 947093 89971 322071 174033 48547 998535 954205 704114 943163 438900 48547 538422 48547 48547",
"output": "0"
},
{
"input": "5 10 20\n10 10 10 10 1",
"output": "1"
},
{
"input": "5 10 11\n10 10 10 10 1",
"output": "2"
},
{
"input": "3 10 10\n4 3 3",
"output": "0"
},
{
"input": "3 5 5\n5 5 5",
"output": "1"
},
{
"input": "3 4 14\n5 5 5",
"output": "0"
},
{
"input": "2 7 10\n1234 1234",
"output": "0"
},
{
"input": "1 5 6\n10",
"output": "0"
},
{
"input": "3 4 6\n1 2 3",
"output": "0"
},
{
"input": "5 10 12\n13 13 13 13 13",
"output": "0"
},
{
"input": "3 4 5\n5 7 9",
"output": "0"
},
{
"input": "3 10 100\n5 5 5",
"output": "0"
},
{
"input": "5 1 2\n2 2 2 2 2",
"output": "0"
},
{
"input": "5 5 5\n5 5 5 5 5",
"output": "2"
},
{
"input": "2 2 5\n5 5",
"output": "0"
},
{
"input": "3 1 4\n2 2 2",
"output": "0"
}
] | 1,664,386,708
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 58
| 109
| 7,270,400
|
n,b,d=map(int,input().split())
lst=list(map(int,input().split()))
free=0
joicerSize=0
for i in range(n):
siz=lst[i]
if(siz<=b):
joicerSize+=siz
if(joicerSize>d):
joicerSize=0
free+=1
print(free)
|
Title: Juicer
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Kolya is going to make fresh orange juice. He has *n* oranges of sizes *a*1,<=*a*2,<=...,<=*a**n*. Kolya will put them in the juicer in the fixed order, starting with orange of size *a*1, then orange of size *a*2 and so on. To be put in the juicer the orange must have size not exceeding *b*, so if Kolya sees an orange that is strictly greater he throws it away and continues with the next one.
The juicer has a special section to collect waste. It overflows if Kolya squeezes oranges of the total size strictly greater than *d*. When it happens Kolya empties the waste section (even if there are no more oranges) and continues to squeeze the juice. How many times will he have to empty the waste section?
Input Specification:
The first line of the input contains three integers *n*, *b* and *d* (1<=≤<=*n*<=≤<=100<=000, 1<=≤<=*b*<=≤<=*d*<=≤<=1<=000<=000) — the number of oranges, the maximum size of the orange that fits in the juicer and the value *d*, which determines the condition when the waste section should be emptied.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=1<=000<=000) — sizes of the oranges listed in the order Kolya is going to try to put them in the juicer.
Output Specification:
Print one integer — the number of times Kolya will have to empty the waste section.
Demo Input:
['2 7 10\n5 6\n', '1 5 10\n7\n', '3 10 10\n5 7 7\n', '1 1 1\n1\n']
Demo Output:
['1\n', '0\n', '1\n', '0\n']
Note:
In the first sample, Kolya will squeeze the juice from two oranges and empty the waste section afterwards.
In the second sample, the orange won't fit in the juicer so Kolya will have no juice at all.
|
```python
n,b,d=map(int,input().split())
lst=list(map(int,input().split()))
free=0
joicerSize=0
for i in range(n):
siz=lst[i]
if(siz<=b):
joicerSize+=siz
if(joicerSize>d):
joicerSize=0
free+=1
print(free)
```
| 3
|
|
792
|
A
|
New Bus Route
|
PROGRAMMING
| 1,100
|
[
"implementation",
"sortings"
] | null | null |
There are *n* cities situated along the main road of Berland. Cities are represented by their coordinates — integer numbers *a*1,<=*a*2,<=...,<=*a**n*. All coordinates are pairwise distinct.
It is possible to get from one city to another only by bus. But all buses and roads are very old, so the Minister of Transport decided to build a new bus route. The Minister doesn't want to spend large amounts of money — he wants to choose two cities in such a way that the distance between them is minimal possible. The distance between two cities is equal to the absolute value of the difference between their coordinates.
It is possible that there are multiple pairs of cities with minimal possible distance, so the Minister wants to know the quantity of such pairs.
Your task is to write a program that will calculate the minimal possible distance between two pairs of cities and the quantity of pairs which have this distance.
|
The first line contains one integer number *n* (2<=≤<=*n*<=≤<=2·105).
The second line contains *n* integer numbers *a*1,<=*a*2,<=...,<=*a**n* (<=-<=109<=≤<=*a**i*<=≤<=109). All numbers *a**i* are pairwise distinct.
|
Print two integer numbers — the minimal distance and the quantity of pairs with this distance.
|
[
"4\n6 -3 0 4\n",
"3\n-2 0 2\n"
] |
[
"2 1\n",
"2 2\n"
] |
In the first example the distance between the first city and the fourth city is |4 - 6| = 2, and it is the only pair with this distance.
| 0
|
[
{
"input": "4\n6 -3 0 4",
"output": "2 1"
},
{
"input": "3\n-2 0 2",
"output": "2 2"
},
{
"input": "2\n1 2",
"output": "1 1"
},
{
"input": "2\n1000000000 -1000000000",
"output": "2000000000 1"
},
{
"input": "5\n-979619606 -979619602 -979619604 -979619605 -979619603",
"output": "1 4"
},
{
"input": "5\n-799147771 -799147773 -799147764 -799147774 -799147770",
"output": "1 2"
},
{
"input": "20\n553280626 553280623 553280627 553280624 553280625 553280618 553280620 553280629 553280637 553280631 553280628 553280636 553280635 553280632 553280634 553280622 553280633 553280621 553280630 553280619",
"output": "1 19"
},
{
"input": "20\n105619866 106083760 106090730 105809555 106115212 105155938 105979518 106075627 106145216 105637844 105925719 105498536 105927000 106155938 106134226 106125969 106130588 105464813 106145509 106114971",
"output": "241 1"
},
{
"input": "10\n570685866 570685854 570685858 570685850 570685856 570685864 570685860 570685852 570685862 570685868",
"output": "2 9"
},
{
"input": "2\n1 1000000000",
"output": "999999999 1"
},
{
"input": "6\n1 2 3 4 5 6",
"output": "1 5"
},
{
"input": "3\n7 10 12",
"output": "2 1"
},
{
"input": "5\n-7 -5 -4 -3 -1",
"output": "1 2"
},
{
"input": "4\n-6 -4 -2 1",
"output": "2 2"
},
{
"input": "4\n3 5 7 8",
"output": "1 1"
},
{
"input": "9\n-9 -8 -7 -6 -5 -4 -3 -2 -1",
"output": "1 8"
},
{
"input": "2\n15 13",
"output": "2 1"
},
{
"input": "2\n14 13",
"output": "1 1"
},
{
"input": "2\n12 13",
"output": "1 1"
},
{
"input": "2\n-1000000000 13265920",
"output": "1013265920 1"
},
{
"input": "2\n8 10",
"output": "2 1"
}
] | 1,689,647,688
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 0
| 46
| 0
|
print("_RANDOM_GUESS_1689647688.1852524")# 1689647688.185273
|
Title: New Bus Route
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There are *n* cities situated along the main road of Berland. Cities are represented by their coordinates — integer numbers *a*1,<=*a*2,<=...,<=*a**n*. All coordinates are pairwise distinct.
It is possible to get from one city to another only by bus. But all buses and roads are very old, so the Minister of Transport decided to build a new bus route. The Minister doesn't want to spend large amounts of money — he wants to choose two cities in such a way that the distance between them is minimal possible. The distance between two cities is equal to the absolute value of the difference between their coordinates.
It is possible that there are multiple pairs of cities with minimal possible distance, so the Minister wants to know the quantity of such pairs.
Your task is to write a program that will calculate the minimal possible distance between two pairs of cities and the quantity of pairs which have this distance.
Input Specification:
The first line contains one integer number *n* (2<=≤<=*n*<=≤<=2·105).
The second line contains *n* integer numbers *a*1,<=*a*2,<=...,<=*a**n* (<=-<=109<=≤<=*a**i*<=≤<=109). All numbers *a**i* are pairwise distinct.
Output Specification:
Print two integer numbers — the minimal distance and the quantity of pairs with this distance.
Demo Input:
['4\n6 -3 0 4\n', '3\n-2 0 2\n']
Demo Output:
['2 1\n', '2 2\n']
Note:
In the first example the distance between the first city and the fourth city is |4 - 6| = 2, and it is the only pair with this distance.
|
```python
print("_RANDOM_GUESS_1689647688.1852524")# 1689647688.185273
```
| 0
|
|
869
|
B
|
The Eternal Immortality
|
PROGRAMMING
| 1,100
|
[
"math"
] | null | null |
Even if the world is full of counterfeits, I still regard it as wonderful.
Pile up herbs and incense, and arise again from the flames and ashes of its predecessor — as is known to many, the phoenix does it like this.
The phoenix has a rather long lifespan, and reincarnates itself once every *a*! years. Here *a*! denotes the factorial of integer *a*, that is, *a*!<==<=1<=×<=2<=×<=...<=×<=*a*. Specifically, 0!<==<=1.
Koyomi doesn't care much about this, but before he gets into another mess with oddities, he is interested in the number of times the phoenix will reincarnate in a timespan of *b*! years, that is, . Note that when *b*<=≥<=*a* this value is always integer.
As the answer can be quite large, it would be enough for Koyomi just to know the last digit of the answer in decimal representation. And you're here to provide Koyomi with this knowledge.
|
The first and only line of input contains two space-separated integers *a* and *b* (0<=≤<=*a*<=≤<=*b*<=≤<=1018).
|
Output one line containing a single decimal digit — the last digit of the value that interests Koyomi.
|
[
"2 4\n",
"0 10\n",
"107 109\n"
] |
[
"2\n",
"0\n",
"2\n"
] |
In the first example, the last digit of <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/99c47ca8b182f097e38094d12f0c06ce0b081b76.png" style="max-width: 100.0%;max-height: 100.0%;"/> is 2;
In the second example, the last digit of <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/9642ef11a23e7c5a3f3c2b1255c1b1b3533802a4.png" style="max-width: 100.0%;max-height: 100.0%;"/> is 0;
In the third example, the last digit of <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/844938cef52ee264c183246d2a9df05cca94dc60.png" style="max-width: 100.0%;max-height: 100.0%;"/> is 2.
| 1,000
|
[
{
"input": "2 4",
"output": "2"
},
{
"input": "0 10",
"output": "0"
},
{
"input": "107 109",
"output": "2"
},
{
"input": "10 13",
"output": "6"
},
{
"input": "998244355 998244359",
"output": "4"
},
{
"input": "999999999000000000 1000000000000000000",
"output": "0"
},
{
"input": "2 3",
"output": "3"
},
{
"input": "3 15",
"output": "0"
},
{
"input": "24 26",
"output": "0"
},
{
"input": "14 60",
"output": "0"
},
{
"input": "11 79",
"output": "0"
},
{
"input": "1230 1232",
"output": "2"
},
{
"input": "2633 2634",
"output": "4"
},
{
"input": "535 536",
"output": "6"
},
{
"input": "344319135 396746843",
"output": "0"
},
{
"input": "696667767 696667767",
"output": "1"
},
{
"input": "419530302 610096911",
"output": "0"
},
{
"input": "238965115 821731161",
"output": "0"
},
{
"input": "414626436 728903812",
"output": "0"
},
{
"input": "274410639 293308324",
"output": "0"
},
{
"input": "650636673091305697 650636673091305702",
"output": "0"
},
{
"input": "651240548333620923 651240548333620924",
"output": "4"
},
{
"input": "500000000000000000 1000000000000000000",
"output": "0"
},
{
"input": "999999999999999999 1000000000000000000",
"output": "0"
},
{
"input": "1000000000000000000 1000000000000000000",
"output": "1"
},
{
"input": "0 4",
"output": "4"
},
{
"input": "50000000062000007 50000000062000011",
"output": "0"
},
{
"input": "0 0",
"output": "1"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "0 2",
"output": "2"
},
{
"input": "10000000000012 10000000000015",
"output": "0"
},
{
"input": "5 5",
"output": "1"
},
{
"input": "12 23",
"output": "0"
},
{
"input": "0 11",
"output": "0"
},
{
"input": "11111234567890 11111234567898",
"output": "0"
},
{
"input": "0 3",
"output": "6"
},
{
"input": "1 2",
"output": "2"
},
{
"input": "999999999999999997 999999999999999999",
"output": "2"
},
{
"input": "4 5",
"output": "5"
},
{
"input": "0 1",
"output": "1"
},
{
"input": "101 1002",
"output": "0"
},
{
"input": "0 100000000000000001",
"output": "0"
},
{
"input": "99999999999999997 99999999999999999",
"output": "2"
},
{
"input": "14 15",
"output": "5"
},
{
"input": "8 19",
"output": "0"
},
{
"input": "12 22",
"output": "0"
},
{
"input": "999999999999996 999999999999999",
"output": "4"
},
{
"input": "1 3",
"output": "6"
},
{
"input": "124 125",
"output": "5"
},
{
"input": "11 32",
"output": "0"
},
{
"input": "0 5",
"output": "0"
},
{
"input": "0 999999",
"output": "0"
},
{
"input": "151151151515 151151151526",
"output": "0"
},
{
"input": "6 107",
"output": "0"
},
{
"input": "5 16",
"output": "0"
},
{
"input": "7 16",
"output": "0"
},
{
"input": "6 19",
"output": "0"
},
{
"input": "11113111111111 13111111111111",
"output": "0"
},
{
"input": "1 1000",
"output": "0"
},
{
"input": "24 25",
"output": "5"
},
{
"input": "0 100000000000",
"output": "0"
},
{
"input": "1 22",
"output": "0"
},
{
"input": "999999999999999996 999999999999999999",
"output": "4"
}
] | 1,508,101,302
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 63
| 62
| 5,529,600
|
L = input()
L = L.split()
a = int(L[0])
b = int(L[1])
def Factorial (N):
k = 1
F = 1
while k <= N:
F *= k
k += 1
return F
if a == b:
print (1)
else:
if a == 0:
if b >= 5:
print (0)
else:
print(Factorial(b)%10)
else:
i = b - a
if i == 1:
print (b%10)
else:
f = 1
M = 0
t = a + f
n = a + f + 1
while f < i and i <= 10:
t = t%10
n = n%10
M = (t*n)%10
f += 1
t = M
n = a + f + 1
print (M)
|
Title: The Eternal Immortality
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Even if the world is full of counterfeits, I still regard it as wonderful.
Pile up herbs and incense, and arise again from the flames and ashes of its predecessor — as is known to many, the phoenix does it like this.
The phoenix has a rather long lifespan, and reincarnates itself once every *a*! years. Here *a*! denotes the factorial of integer *a*, that is, *a*!<==<=1<=×<=2<=×<=...<=×<=*a*. Specifically, 0!<==<=1.
Koyomi doesn't care much about this, but before he gets into another mess with oddities, he is interested in the number of times the phoenix will reincarnate in a timespan of *b*! years, that is, . Note that when *b*<=≥<=*a* this value is always integer.
As the answer can be quite large, it would be enough for Koyomi just to know the last digit of the answer in decimal representation. And you're here to provide Koyomi with this knowledge.
Input Specification:
The first and only line of input contains two space-separated integers *a* and *b* (0<=≤<=*a*<=≤<=*b*<=≤<=1018).
Output Specification:
Output one line containing a single decimal digit — the last digit of the value that interests Koyomi.
Demo Input:
['2 4\n', '0 10\n', '107 109\n']
Demo Output:
['2\n', '0\n', '2\n']
Note:
In the first example, the last digit of <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/99c47ca8b182f097e38094d12f0c06ce0b081b76.png" style="max-width: 100.0%;max-height: 100.0%;"/> is 2;
In the second example, the last digit of <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/9642ef11a23e7c5a3f3c2b1255c1b1b3533802a4.png" style="max-width: 100.0%;max-height: 100.0%;"/> is 0;
In the third example, the last digit of <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/844938cef52ee264c183246d2a9df05cca94dc60.png" style="max-width: 100.0%;max-height: 100.0%;"/> is 2.
|
```python
L = input()
L = L.split()
a = int(L[0])
b = int(L[1])
def Factorial (N):
k = 1
F = 1
while k <= N:
F *= k
k += 1
return F
if a == b:
print (1)
else:
if a == 0:
if b >= 5:
print (0)
else:
print(Factorial(b)%10)
else:
i = b - a
if i == 1:
print (b%10)
else:
f = 1
M = 0
t = a + f
n = a + f + 1
while f < i and i <= 10:
t = t%10
n = n%10
M = (t*n)%10
f += 1
t = M
n = a + f + 1
print (M)
```
| 3
|
|
540
|
A
|
Combination Lock
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Scrooge McDuck keeps his most treasured savings in a home safe with a combination lock. Each time he wants to put there the treasures that he's earned fair and square, he has to open the lock.
The combination lock is represented by *n* rotating disks with digits from 0 to 9 written on them. Scrooge McDuck has to turn some disks so that the combination of digits on the disks forms a secret combination. In one move, he can rotate one disk one digit forwards or backwards. In particular, in one move he can go from digit 0 to digit 9 and vice versa. What minimum number of actions does he need for that?
|
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of disks on the combination lock.
The second line contains a string of *n* digits — the original state of the disks.
The third line contains a string of *n* digits — Scrooge McDuck's combination that opens the lock.
|
Print a single integer — the minimum number of moves Scrooge McDuck needs to open the lock.
|
[
"5\n82195\n64723\n"
] |
[
"13\n"
] |
In the sample he needs 13 moves:
- 1 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b8967f65a723782358b93eff9ce69f336817cf70.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 2 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/07fa58573ece0d32c4d555e498d2b24d2f70f36a.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 3 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/cc2275d9252aae35a6867c6a5b4ba7596e9a7626.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 4 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b100aea470fcaaab4e9529b234ba0d7875943c10.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 5 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/eb2cbe4324cebca65b85816262a85e473cd65967.png" style="max-width: 100.0%;max-height: 100.0%;"/>
| 500
|
[
{
"input": "5\n82195\n64723",
"output": "13"
},
{
"input": "12\n102021090898\n010212908089",
"output": "16"
},
{
"input": "1\n8\n1",
"output": "3"
},
{
"input": "2\n83\n57",
"output": "7"
},
{
"input": "10\n0728592530\n1362615763",
"output": "27"
},
{
"input": "100\n4176196363694273682807653052945037727131821799902563705176501742060696655282954944720643131654235909\n3459912084922154505910287499879975659298239371519889866585472674423008837878123067103005344986554746",
"output": "245"
},
{
"input": "1\n8\n1",
"output": "3"
},
{
"input": "2\n83\n57",
"output": "7"
},
{
"input": "3\n607\n684",
"output": "5"
},
{
"input": "4\n0809\n0636",
"output": "8"
},
{
"input": "5\n84284\n08941",
"output": "16"
},
{
"input": "25\n8037856825987124762280548\n9519431339078678836940020",
"output": "72"
},
{
"input": "125\n23269567683904664184142384849516523616863461607751021071772615078579713054027902974007001544768640273491193035874486891541257\n47635110303703399505805044019026243695451609639556649012447370081552870340011971572363458960190590266459684717415349529509024",
"output": "305"
},
{
"input": "5\n84284\n08941",
"output": "16"
},
{
"input": "25\n8037856825987124762285484\n9519431339078678836940202",
"output": "74"
},
{
"input": "125\n23269567689466418414238845152168634610771021717726157879713054270294007001544768647391193035874486891412573389247025830678706\n47635110307339950580504010224954516093956649124473708152870340117152363458960190596659684717415349529090241694059599629136831",
"output": "357"
},
{
"input": "5\n84284\n08941",
"output": "16"
},
{
"input": "25\n8378525987476228048406972\n9194339078883694020217816",
"output": "55"
},
{
"input": "125\n23269576839046618414238484916523616863461607750210717761078579713054027902974007015447686027349193035874486891541257338624472\n47635103037033950580504401926243695451609639556490124437081552870340011971572363489601905026645984717415349529509024169604599",
"output": "274"
},
{
"input": "1\n0\n0",
"output": "0"
},
{
"input": "1\n7\n7",
"output": "0"
},
{
"input": "1\n0\n5",
"output": "5"
},
{
"input": "1\n2\n7",
"output": "5"
},
{
"input": "1\n7\n9",
"output": "2"
},
{
"input": "1\n9\n7",
"output": "2"
},
{
"input": "1\n2\n9",
"output": "3"
},
{
"input": "1\n9\n2",
"output": "3"
},
{
"input": "25\n3164978461316464614169874\n9413979197249127496597357",
"output": "66"
},
{
"input": "4\n9999\n9999",
"output": "0"
},
{
"input": "2\n11\n11",
"output": "0"
}
] | 1,641,995,560
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 43
| 46
| 0
|
t=int(input())
s=input()
c=0
l=input()
for i in range(t):
m=abs(int(s[i])-int(l[i]))
if m>5:
m=abs(10-m)
c=c+m
print(c)
|
Title: Combination Lock
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Scrooge McDuck keeps his most treasured savings in a home safe with a combination lock. Each time he wants to put there the treasures that he's earned fair and square, he has to open the lock.
The combination lock is represented by *n* rotating disks with digits from 0 to 9 written on them. Scrooge McDuck has to turn some disks so that the combination of digits on the disks forms a secret combination. In one move, he can rotate one disk one digit forwards or backwards. In particular, in one move he can go from digit 0 to digit 9 and vice versa. What minimum number of actions does he need for that?
Input Specification:
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of disks on the combination lock.
The second line contains a string of *n* digits — the original state of the disks.
The third line contains a string of *n* digits — Scrooge McDuck's combination that opens the lock.
Output Specification:
Print a single integer — the minimum number of moves Scrooge McDuck needs to open the lock.
Demo Input:
['5\n82195\n64723\n']
Demo Output:
['13\n']
Note:
In the sample he needs 13 moves:
- 1 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b8967f65a723782358b93eff9ce69f336817cf70.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 2 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/07fa58573ece0d32c4d555e498d2b24d2f70f36a.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 3 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/cc2275d9252aae35a6867c6a5b4ba7596e9a7626.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 4 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b100aea470fcaaab4e9529b234ba0d7875943c10.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 5 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/eb2cbe4324cebca65b85816262a85e473cd65967.png" style="max-width: 100.0%;max-height: 100.0%;"/>
|
```python
t=int(input())
s=input()
c=0
l=input()
for i in range(t):
m=abs(int(s[i])-int(l[i]))
if m>5:
m=abs(10-m)
c=c+m
print(c)
```
| 3
|
|
166
|
C
|
Median
|
PROGRAMMING
| 1,500
|
[
"greedy",
"math",
"sortings"
] | null | null |
A median in an array with the length of *n* is an element which occupies position number after we sort the elements in the non-decreasing order (the array elements are numbered starting with 1). A median of an array (2,<=6,<=1,<=2,<=3) is the number 2, and a median of array (0,<=96,<=17,<=23) — the number 17.
We define an expression as the integer part of dividing number *a* by number *b*.
One day Vasya showed Petya an array consisting of *n* integers and suggested finding the array's median. Petya didn't even look at the array and said that it equals *x*. Petya is a very honest boy, so he decided to add several numbers to the given array so that the median of the resulting array would be equal to *x*.
Petya can add any integers from 1 to 105 to the array, including the same numbers. Of course, he can add nothing to the array. If a number is added multiple times, then we should consider it the number of times it occurs. It is not allowed to delete of change initial numbers of the array.
While Petya is busy distracting Vasya, your task is to find the minimum number of elements he will need.
|
The first input line contains two space-separated integers *n* and *x* (1<=≤<=*n*<=≤<=500, 1<=≤<=*x*<=≤<=105) — the initial array's length and the required median's value. The second line contains *n* space-separated numbers — the initial array. The elements of the array are integers from 1 to 105. The array elements are not necessarily different.
|
Print the only integer — the minimum number of elements Petya needs to add to the array so that its median equals *x*.
|
[
"3 10\n10 20 30\n",
"3 4\n1 2 3\n"
] |
[
"1\n",
"4\n"
] |
In the first sample we can add number 9 to array (10, 20, 30). The resulting array (9, 10, 20, 30) will have a median in position <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/7dd92241318a531b780c7783dfa446a3e413115e.png" style="max-width: 100.0%;max-height: 100.0%;"/>, that is, 10.
In the second sample you should add numbers 4, 5, 5, 5. The resulting array has median equal to 4.
| 1,000
|
[
{
"input": "3 10\n10 20 30",
"output": "1"
},
{
"input": "3 4\n1 2 3",
"output": "4"
},
{
"input": "2 2\n3 2",
"output": "0"
},
{
"input": "5 1\n1 1 2 1 2",
"output": "0"
},
{
"input": "5 4\n5 5 4 3 5",
"output": "1"
},
{
"input": "10 2\n2 2 1 3 2 1 2 1 1 3",
"output": "0"
},
{
"input": "10 55749\n46380 58202 54935 26290 18295 83040 6933 89652 75187 93963",
"output": "1"
},
{
"input": "10 809\n949 31 175 118 640 588 809 398 792 743",
"output": "7"
},
{
"input": "50 1\n1 2 1 2 1 1 1 2 2 2 2 2 1 1 2 2 2 2 1 2 2 2 1 2 1 1 2 1 1 1 2 2 2 2 2 2 2 2 1 2 2 1 1 1 2 2 1 2 2 2",
"output": "12"
},
{
"input": "100 6\n7 5 2 8 4 9 4 8 6 1 7 8 7 8 1 5 4 10 9 10 7 5 6 2 1 6 9 10 6 5 10 9 9 5 1 4 4 5 4 4 1 1 6 7 4 9 3 5 6 5 6 3 7 6 9 4 4 8 7 10 6 10 4 6 6 5 1 9 6 7 10 1 9 4 5 3 7 7 4 4 7 4 7 3 3 7 2 5 5 3 8 9 6 9 4 5 5 9 1 7",
"output": "0"
},
{
"input": "100 813\n285 143 378 188 972 950 222 557 170 755 470 164 800 553 146 820 842 62 496 980 746 944 677 828 465 577 791 277 303 515 561 653 925 692 871 424 626 795 813 343 418 280 123 364 496 447 435 404 645 141 169 315 830 289 450 675 81 212 509 661 7 217 468 877 172 141 475 409 178 71 936 843 761 889 417 282 530 612 328 572 310 632 498 271 19 753 3 787 31 266 251 897 450 206 731 678 64 417 664 224",
"output": "69"
},
{
"input": "100 37\n20 20 3 35 36 14 30 9 33 36 32 46 43 22 43 50 34 6 13 25 1 34 10 6 21 30 19 17 1 23 9 23 38 21 7 43 49 28 33 42 4 19 39 23 12 42 31 13 26 23 1 26 24 48 10 6 12 48 40 18 10 26 9 5 22 45 46 23 46 34 34 45 3 7 16 39 14 29 48 1 12 37 4 20 29 26 35 38 20 47 39 29 12 35 4 32 26 1 50 33",
"output": "53"
},
{
"input": "100 20\n40 44 41 81 59 96 91 49 57 41 44 42 65 31 74 70 54 47 51 7 71 7 75 79 13 20 2 78 66 34 81 84 18 37 85 42 5 40 17 15 66 10 95 93 20 43 63 83 60 61 9 33 68 81 97 25 39 37 22 90 63 45 33 89 1 68 37 66 89 86 6 29 40 33 44 11 83 21 11 32 92 41 45 79 29 86 89 87 14 1 32 22 25 90 56 6 1 49 15 89",
"output": "58"
},
{
"input": "1 1\n1",
"output": "0"
},
{
"input": "1 2\n1",
"output": "2"
},
{
"input": "1 1\n2",
"output": "1"
},
{
"input": "4 1\n2 3 4 5",
"output": "4"
},
{
"input": "9 228\n1 1 1 1 1 1 228 228 228",
"output": "4"
}
] | 1,687,364,934
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 5
| 124
| 0
|
def main():
n, x = list(map(int, input().split()))
a = list(map(int, input().split()))
a.sort()
index = -1
for i in range(1, n):
if a[i-1]<= x < a[i]:
index = i-1
break
if index == -1:
if a[0] < x:
index = n-1
if index+1 < (n + 1) // 2:
ans = 0
while index != (n + 1)//2-1:
index += 1
ans += 1
n += 1
print(ans)
elif index+1 == (n + 1) // 2:
if a[index] == x:
print(0)
else:
print(1)
else:
ans = 0
if a[index] == x:
while index != (n + 1) // 2 - 1:
n += 1
ans += 1
print(ans)
else:
index += 1
ans = 1
n += 1
while index != (n + 1) // 2 - 1:
n += 1
ans += 1
print(ans)
if __name__ == "__main__":
main()
|
Title: Median
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A median in an array with the length of *n* is an element which occupies position number after we sort the elements in the non-decreasing order (the array elements are numbered starting with 1). A median of an array (2,<=6,<=1,<=2,<=3) is the number 2, and a median of array (0,<=96,<=17,<=23) — the number 17.
We define an expression as the integer part of dividing number *a* by number *b*.
One day Vasya showed Petya an array consisting of *n* integers and suggested finding the array's median. Petya didn't even look at the array and said that it equals *x*. Petya is a very honest boy, so he decided to add several numbers to the given array so that the median of the resulting array would be equal to *x*.
Petya can add any integers from 1 to 105 to the array, including the same numbers. Of course, he can add nothing to the array. If a number is added multiple times, then we should consider it the number of times it occurs. It is not allowed to delete of change initial numbers of the array.
While Petya is busy distracting Vasya, your task is to find the minimum number of elements he will need.
Input Specification:
The first input line contains two space-separated integers *n* and *x* (1<=≤<=*n*<=≤<=500, 1<=≤<=*x*<=≤<=105) — the initial array's length and the required median's value. The second line contains *n* space-separated numbers — the initial array. The elements of the array are integers from 1 to 105. The array elements are not necessarily different.
Output Specification:
Print the only integer — the minimum number of elements Petya needs to add to the array so that its median equals *x*.
Demo Input:
['3 10\n10 20 30\n', '3 4\n1 2 3\n']
Demo Output:
['1\n', '4\n']
Note:
In the first sample we can add number 9 to array (10, 20, 30). The resulting array (9, 10, 20, 30) will have a median in position <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/7dd92241318a531b780c7783dfa446a3e413115e.png" style="max-width: 100.0%;max-height: 100.0%;"/>, that is, 10.
In the second sample you should add numbers 4, 5, 5, 5. The resulting array has median equal to 4.
|
```python
def main():
n, x = list(map(int, input().split()))
a = list(map(int, input().split()))
a.sort()
index = -1
for i in range(1, n):
if a[i-1]<= x < a[i]:
index = i-1
break
if index == -1:
if a[0] < x:
index = n-1
if index+1 < (n + 1) // 2:
ans = 0
while index != (n + 1)//2-1:
index += 1
ans += 1
n += 1
print(ans)
elif index+1 == (n + 1) // 2:
if a[index] == x:
print(0)
else:
print(1)
else:
ans = 0
if a[index] == x:
while index != (n + 1) // 2 - 1:
n += 1
ans += 1
print(ans)
else:
index += 1
ans = 1
n += 1
while index != (n + 1) // 2 - 1:
n += 1
ans += 1
print(ans)
if __name__ == "__main__":
main()
```
| 0
|
|
22
|
A
|
Second Order Statistics
|
PROGRAMMING
| 800
|
[
"brute force"
] |
A. Second Order Statistics
|
2
|
256
|
Once Bob needed to find the second order statistics of a sequence of integer numbers. Lets choose each number from the sequence exactly once and sort them. The value on the second position is the second order statistics of the given sequence. In other words it is the smallest element strictly greater than the minimum. Help Bob solve this problem.
|
The first input line contains integer *n* (1<=≤<=*n*<=≤<=100) — amount of numbers in the sequence. The second line contains *n* space-separated integer numbers — elements of the sequence. These numbers don't exceed 100 in absolute value.
|
If the given sequence has the second order statistics, output this order statistics, otherwise output NO.
|
[
"4\n1 2 2 -4\n",
"5\n1 2 3 1 1\n"
] |
[
"1\n",
"2\n"
] |
none
| 0
|
[
{
"input": "4\n1 2 2 -4",
"output": "1"
},
{
"input": "5\n1 2 3 1 1",
"output": "2"
},
{
"input": "1\n28",
"output": "NO"
},
{
"input": "2\n-28 12",
"output": "12"
},
{
"input": "3\n-83 40 -80",
"output": "-80"
},
{
"input": "8\n93 77 -92 26 21 -48 53 91",
"output": "-48"
},
{
"input": "20\n-72 -9 -86 80 7 -10 40 -27 -94 92 96 56 28 -19 79 36 -3 -73 -63 -49",
"output": "-86"
},
{
"input": "49\n-74 -100 -80 23 -8 -83 -41 -20 48 17 46 -73 -55 67 85 4 40 -60 -69 -75 56 -74 -42 93 74 -95 64 -46 97 -47 55 0 -78 -34 -31 40 -63 -49 -76 48 21 -1 -49 -29 -98 -11 76 26 94",
"output": "-98"
},
{
"input": "88\n63 48 1 -53 -89 -49 64 -70 -49 71 -17 -16 76 81 -26 -50 67 -59 -56 97 2 100 14 18 -91 -80 42 92 -25 -88 59 8 -56 38 48 -71 -78 24 -14 48 -1 69 73 -76 54 16 -92 44 47 33 -34 -17 -81 21 -59 -61 53 26 10 -76 67 35 -29 70 65 -13 -29 81 80 32 74 -6 34 46 57 1 -45 -55 69 79 -58 11 -2 22 -18 -16 -89 -46",
"output": "-91"
},
{
"input": "100\n34 32 88 20 76 53 -71 -39 -98 -10 57 37 63 -3 -54 -64 -78 -82 73 20 -30 -4 22 75 51 -64 -91 29 -52 -48 83 19 18 -47 46 57 -44 95 89 89 -30 84 -83 67 58 -99 -90 -53 92 -60 -5 -56 -61 27 68 -48 52 -95 64 -48 -30 -67 66 89 14 -33 -31 -91 39 7 -94 -54 92 -96 -99 -83 -16 91 -28 -66 81 44 14 -85 -21 18 40 16 -13 -82 -33 47 -10 -40 -19 10 25 60 -34 -89",
"output": "-98"
},
{
"input": "2\n-1 -1",
"output": "NO"
},
{
"input": "3\n-2 -2 -2",
"output": "NO"
},
{
"input": "100\n0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0",
"output": "NO"
},
{
"input": "100\n100 100 100 100 100 100 100 100 100 100 100 100 -100 100 100 100 100 100 100 100 100 100 100 100 -100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 -100 100 100 100 100 100 100 100 100 100 100 -100 100 100 100 100 -100 100 100 100 100 100 100 100 100 100 100 100",
"output": "100"
},
{
"input": "10\n40 71 -85 -85 40 -85 -85 64 -85 47",
"output": "40"
},
{
"input": "23\n-90 -90 -41 -64 -64 -90 -15 10 -43 -90 -64 -64 89 -64 36 47 38 -90 -64 -90 -90 68 -90",
"output": "-64"
},
{
"input": "39\n-97 -93 -42 -93 -97 -93 56 -97 -97 -97 76 -33 -60 91 7 82 17 47 -97 -97 -93 73 -97 12 -97 -97 -97 -97 56 -92 -83 -93 -93 49 -93 -97 -97 -17 -93",
"output": "-93"
},
{
"input": "51\n-21 6 -35 -98 -86 -98 -86 -43 -65 32 -98 -40 96 -98 -98 -98 -98 -86 -86 -98 56 -86 -98 -98 -30 -98 -86 -31 -98 -86 -86 -86 -86 -30 96 -86 -86 -86 -60 25 88 -86 -86 58 31 -47 57 -86 37 44 -83",
"output": "-86"
},
{
"input": "66\n-14 -95 65 -95 -95 -97 -90 -71 -97 -97 70 -95 -95 -97 -95 -27 35 -87 -95 -5 -97 -97 87 34 -49 -95 -97 -95 -97 -95 -30 -95 -97 47 -95 -17 -97 -95 -97 -69 51 -97 -97 -95 -75 87 59 21 63 56 76 -91 98 -97 6 -97 -95 -95 -97 -73 11 -97 -35 -95 -95 -43",
"output": "-95"
},
{
"input": "77\n-67 -93 -93 -92 97 29 93 -93 -93 -5 -93 -7 60 -92 -93 44 -84 68 -92 -93 69 -92 -37 56 43 -93 35 -92 -93 19 -79 18 -92 -93 -93 -37 -93 -47 -93 -92 -92 74 67 19 40 -92 -92 -92 -92 -93 -93 -41 -93 -92 -93 -93 -92 -93 51 -80 6 -42 -92 -92 -66 -12 -92 -92 -3 93 -92 -49 -93 40 62 -92 -92",
"output": "-92"
},
{
"input": "89\n-98 40 16 -87 -98 63 -100 55 -96 -98 -21 -100 -93 26 -98 -98 -100 -89 -98 -5 -65 -28 -100 -6 -66 67 -100 -98 -98 10 -98 -98 -70 7 -98 2 -100 -100 -98 25 -100 -100 -98 23 -68 -100 -98 3 98 -100 -98 -98 -98 -98 -24 -100 -100 -9 -98 35 -100 99 -5 -98 -100 -100 37 -100 -84 57 -98 40 -47 -100 -1 -92 -76 -98 -98 -100 -100 -100 -63 30 21 -100 -100 -100 -12",
"output": "-98"
},
{
"input": "99\n10 -84 -100 -100 73 -64 -100 -94 33 -100 -100 -100 -100 71 64 24 7 -100 -32 -100 -100 77 -100 62 -12 55 45 -100 -100 -80 -100 -100 -100 -100 -100 -100 -100 -100 -100 -39 -48 -100 -34 47 -100 -100 -100 -100 -100 -77 -100 -100 -100 -100 -100 -100 -52 40 -55 -100 -44 -100 72 33 70 -100 -100 -78 -100 -3 100 -77 22 -100 95 -30 -100 10 -69 -100 -100 -100 -100 52 -39 -100 -100 -100 7 -100 -98 -66 95 -17 -100 52 -100 68 -100",
"output": "-98"
},
{
"input": "100\n-99 -98 -64 89 53 57 -99 29 -78 18 -3 -54 76 -98 -99 -98 37 -98 19 -47 89 73 -98 -91 -99 -99 -98 -48 -99 22 -99 -98 -99 -99 -98 -60 84 67 -99 -98 20 -98 88 -98 46 -98 -99 -98 -99 -71 -99 -98 -98 -39 83 95 -98 63 -98 -99 32 -98 -99 -64 57 -30 -53 -83 -4 -99 58 20 -98 -10 -99 -44 -99 -99 -99 -99 75 34 -98 -52 -98 -30 -98 -99 -98 -98 51 -99 -99 -99 -98 -99 -99 -82 -90 92",
"output": "-98"
},
{
"input": "3\n1 2 3",
"output": "2"
},
{
"input": "3\n1 3 2",
"output": "2"
},
{
"input": "3\n2 1 3",
"output": "2"
},
{
"input": "3\n2 3 1",
"output": "2"
},
{
"input": "3\n3 1 2",
"output": "2"
},
{
"input": "3\n3 2 1",
"output": "2"
},
{
"input": "9\n99 99 99 99 100 100 100 100 100",
"output": "100"
},
{
"input": "5\n-100 -100 -100 -100 -100",
"output": "NO"
}
] | 1,515,678,028
| 2,147,483,647
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 2
| 122
| 5,632,000
|
m = input()
n = list(map(int, input().split()))
n = sorted(set(n))
print(n[1])
|
Title: Second Order Statistics
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Once Bob needed to find the second order statistics of a sequence of integer numbers. Lets choose each number from the sequence exactly once and sort them. The value on the second position is the second order statistics of the given sequence. In other words it is the smallest element strictly greater than the minimum. Help Bob solve this problem.
Input Specification:
The first input line contains integer *n* (1<=≤<=*n*<=≤<=100) — amount of numbers in the sequence. The second line contains *n* space-separated integer numbers — elements of the sequence. These numbers don't exceed 100 in absolute value.
Output Specification:
If the given sequence has the second order statistics, output this order statistics, otherwise output NO.
Demo Input:
['4\n1 2 2 -4\n', '5\n1 2 3 1 1\n']
Demo Output:
['1\n', '2\n']
Note:
none
|
```python
m = input()
n = list(map(int, input().split()))
n = sorted(set(n))
print(n[1])
```
| -1
|
38
|
B
|
Chess
|
PROGRAMMING
| 1,200
|
[
"brute force",
"implementation",
"math"
] |
B. Chess
|
2
|
256
|
Two chess pieces, a rook and a knight, stand on a standard chessboard 8<=×<=8 in size. The positions in which they are situated are known. It is guaranteed that none of them beats the other one.
Your task is to find the number of ways to place another knight on the board so that none of the three pieces on the board beat another one. A new piece can only be placed on an empty square.
|
The first input line contains the description of the rook's position on the board. This description is a line which is 2 in length. Its first symbol is a lower-case Latin letter from a to h, and its second symbol is a number from 1 to 8. The second line contains the description of the knight's position in a similar way. It is guaranteed that their positions do not coincide.
|
Print a single number which is the required number of ways.
|
[
"a1\nb2\n",
"a8\nd4\n"
] |
[
"44\n",
"38\n"
] |
none
| 0
|
[
{
"input": "a1\nb2",
"output": "44"
},
{
"input": "a8\nd4",
"output": "38"
},
{
"input": "a8\nf1",
"output": "42"
},
{
"input": "f8\nh3",
"output": "42"
},
{
"input": "g8\nb7",
"output": "42"
},
{
"input": "h1\ng5",
"output": "42"
},
{
"input": "c6\nb5",
"output": "39"
},
{
"input": "c1\nd2",
"output": "42"
},
{
"input": "g3\nh4",
"output": "42"
},
{
"input": "e3\ng5",
"output": "38"
},
{
"input": "f8\na3",
"output": "40"
},
{
"input": "a2\nh8",
"output": "43"
},
{
"input": "a3\nc5",
"output": "40"
},
{
"input": "g1\ne6",
"output": "39"
},
{
"input": "e1\na7",
"output": "41"
},
{
"input": "b5\nc1",
"output": "39"
},
{
"input": "b2\ne1",
"output": "43"
},
{
"input": "h8\ng2",
"output": "43"
},
{
"input": "a3\nd6",
"output": "38"
},
{
"input": "g6\nb7",
"output": "39"
},
{
"input": "c8\ne6",
"output": "40"
},
{
"input": "e6\nf2",
"output": "35"
},
{
"input": "b6\nd8",
"output": "41"
},
{
"input": "a4\nd1",
"output": "42"
},
{
"input": "b5\nh8",
"output": "40"
},
{
"input": "h6\na1",
"output": "42"
},
{
"input": "c3\na8",
"output": "39"
},
{
"input": "g5\nd2",
"output": "38"
},
{
"input": "b6\ng7",
"output": "39"
},
{
"input": "h6\na8",
"output": "43"
},
{
"input": "a8\nb7",
"output": "44"
},
{
"input": "c8\nb2",
"output": "41"
},
{
"input": "e4\nc1",
"output": "37"
},
{
"input": "f1\nc3",
"output": "38"
},
{
"input": "a3\nc8",
"output": "41"
},
{
"input": "e8\nb6",
"output": "40"
},
{
"input": "a1\nb7",
"output": "43"
},
{
"input": "g2\nb7",
"output": "40"
},
{
"input": "e1\nd6",
"output": "38"
},
{
"input": "e5\nh6",
"output": "39"
}
] | 1,689,151,678
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 40
| 124
| 0
|
dict1={"a":1,"b":2,"c":3,"d":4,"e":5,"f":6,"g":7,"h":8}
r=input()
k=input()
r=[dict1[r[0]],int(r[1])]
k=[dict1[k[0]],int(k[1])]
c=64
x,y=k
kk=[[x,y],[x-2,y+1],[x-2,y-1],[x-1,y+2],[x+1,y+2],[x+2,y+1],[x+2,y-1],[x+1,y-2],[x-1,y-2]]
x,y=r
rr=[[x,y],[x-2,y+1],[x-2,y-1],[x-1,y+2],[x+1,y+2],[x+2,y+1],[x+2,y-1],[x+1,y-2],[x-1,y-2]]
kk+=rr
for i in range(1,9):
for t in range(1,9):
if i==r[0] or t==r[1] or [i,t] in kk:
c-=1
print(c)
|
Title: Chess
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Two chess pieces, a rook and a knight, stand on a standard chessboard 8<=×<=8 in size. The positions in which they are situated are known. It is guaranteed that none of them beats the other one.
Your task is to find the number of ways to place another knight on the board so that none of the three pieces on the board beat another one. A new piece can only be placed on an empty square.
Input Specification:
The first input line contains the description of the rook's position on the board. This description is a line which is 2 in length. Its first symbol is a lower-case Latin letter from a to h, and its second symbol is a number from 1 to 8. The second line contains the description of the knight's position in a similar way. It is guaranteed that their positions do not coincide.
Output Specification:
Print a single number which is the required number of ways.
Demo Input:
['a1\nb2\n', 'a8\nd4\n']
Demo Output:
['44\n', '38\n']
Note:
none
|
```python
dict1={"a":1,"b":2,"c":3,"d":4,"e":5,"f":6,"g":7,"h":8}
r=input()
k=input()
r=[dict1[r[0]],int(r[1])]
k=[dict1[k[0]],int(k[1])]
c=64
x,y=k
kk=[[x,y],[x-2,y+1],[x-2,y-1],[x-1,y+2],[x+1,y+2],[x+2,y+1],[x+2,y-1],[x+1,y-2],[x-1,y-2]]
x,y=r
rr=[[x,y],[x-2,y+1],[x-2,y-1],[x-1,y+2],[x+1,y+2],[x+2,y+1],[x+2,y-1],[x+1,y-2],[x-1,y-2]]
kk+=rr
for i in range(1,9):
for t in range(1,9):
if i==r[0] or t==r[1] or [i,t] in kk:
c-=1
print(c)
```
| 3.969
|
702
|
A
|
Maximum Increase
|
PROGRAMMING
| 800
|
[
"dp",
"greedy",
"implementation"
] | null | null |
You are given array consisting of *n* integers. Your task is to find the maximum length of an increasing subarray of the given array.
A subarray is the sequence of consecutive elements of the array. Subarray is called increasing if each element of this subarray strictly greater than previous.
|
The first line contains single positive integer *n* (1<=≤<=*n*<=≤<=105) — the number of integers.
The second line contains *n* positive integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109).
|
Print the maximum length of an increasing subarray of the given array.
|
[
"5\n1 7 2 11 15\n",
"6\n100 100 100 100 100 100\n",
"3\n1 2 3\n"
] |
[
"3\n",
"1\n",
"3\n"
] |
none
| 0
|
[
{
"input": "5\n1 7 2 11 15",
"output": "3"
},
{
"input": "6\n100 100 100 100 100 100",
"output": "1"
},
{
"input": "3\n1 2 3",
"output": "3"
},
{
"input": "1\n1000000000",
"output": "1"
},
{
"input": "10\n802030518 598196518 640274071 983359971 71550121 96204862 799843967 446173607 796619138 402690754",
"output": "3"
},
{
"input": "2\n2 1",
"output": "1"
},
{
"input": "5\n1 2 3 3 4",
"output": "3"
},
{
"input": "4\n1 2 2 3",
"output": "2"
},
{
"input": "3\n2 1 1",
"output": "1"
},
{
"input": "3\n1 2 1",
"output": "2"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "2\n1 2",
"output": "2"
},
{
"input": "3\n1 1 2",
"output": "2"
},
{
"input": "11\n1 2 3 1 2 3 2 1 2 3 4",
"output": "4"
},
{
"input": "9\n1 2 3 4 5 6 7 8 9",
"output": "9"
},
{
"input": "9\n1 1 1 1 1 1 1 1 1",
"output": "1"
},
{
"input": "3\n3 2 1",
"output": "1"
},
{
"input": "7\n1 2 3 4 5 6 7",
"output": "7"
},
{
"input": "1\n1234394",
"output": "1"
}
] | 1,691,073,853
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 32
| 186
| 10,649,600
|
n=int(input())
nums=[int(i) for i in input().split()]
i=0
maxi=1
for j in range(1,n):
if nums[j]<=nums[j-1]:
i=j
maxi=max(maxi,j-i+1)
print(maxi)
|
Title: Maximum Increase
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given array consisting of *n* integers. Your task is to find the maximum length of an increasing subarray of the given array.
A subarray is the sequence of consecutive elements of the array. Subarray is called increasing if each element of this subarray strictly greater than previous.
Input Specification:
The first line contains single positive integer *n* (1<=≤<=*n*<=≤<=105) — the number of integers.
The second line contains *n* positive integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109).
Output Specification:
Print the maximum length of an increasing subarray of the given array.
Demo Input:
['5\n1 7 2 11 15\n', '6\n100 100 100 100 100 100\n', '3\n1 2 3\n']
Demo Output:
['3\n', '1\n', '3\n']
Note:
none
|
```python
n=int(input())
nums=[int(i) for i in input().split()]
i=0
maxi=1
for j in range(1,n):
if nums[j]<=nums[j-1]:
i=j
maxi=max(maxi,j-i+1)
print(maxi)
```
| 3
|
|
990
|
A
|
Commentary Boxes
|
PROGRAMMING
| 1,000
|
[
"implementation",
"math"
] | null | null |
Berland Football Cup starts really soon! Commentators from all over the world come to the event.
Organizers have already built $n$ commentary boxes. $m$ regional delegations will come to the Cup. Every delegation should get the same number of the commentary boxes. If any box is left unoccupied then the delegations will be upset. So each box should be occupied by exactly one delegation.
If $n$ is not divisible by $m$, it is impossible to distribute the boxes to the delegations at the moment.
Organizers can build a new commentary box paying $a$ burles and demolish a commentary box paying $b$ burles. They can both build and demolish boxes arbitrary number of times (each time paying a corresponding fee). It is allowed to demolish all the existing boxes.
What is the minimal amount of burles organizers should pay to satisfy all the delegations (i.e. to make the number of the boxes be divisible by $m$)?
|
The only line contains four integer numbers $n$, $m$, $a$ and $b$ ($1 \le n, m \le 10^{12}$, $1 \le a, b \le 100$), where $n$ is the initial number of the commentary boxes, $m$ is the number of delegations to come, $a$ is the fee to build a box and $b$ is the fee to demolish a box.
|
Output the minimal amount of burles organizers should pay to satisfy all the delegations (i.e. to make the number of the boxes be divisible by $m$). It is allowed that the final number of the boxes is equal to $0$.
|
[
"9 7 3 8\n",
"2 7 3 7\n",
"30 6 17 19\n"
] |
[
"15\n",
"14\n",
"0\n"
] |
In the first example organizers can build $5$ boxes to make the total of $14$ paying $3$ burles for the each of them.
In the second example organizers can demolish $2$ boxes to make the total of $0$ paying $7$ burles for the each of them.
In the third example organizers are already able to distribute all the boxes equally among the delegations, each one get $5$ boxes.
| 0
|
[
{
"input": "9 7 3 8",
"output": "15"
},
{
"input": "2 7 3 7",
"output": "14"
},
{
"input": "30 6 17 19",
"output": "0"
},
{
"input": "500000000001 1000000000000 100 100",
"output": "49999999999900"
},
{
"input": "1000000000000 750000000001 10 100",
"output": "5000000000020"
},
{
"input": "1000000000000 750000000001 100 10",
"output": "2499999999990"
},
{
"input": "42 1 1 1",
"output": "0"
},
{
"input": "1 1000000000000 1 100",
"output": "100"
},
{
"input": "7 2 3 7",
"output": "3"
},
{
"input": "999999999 2 1 1",
"output": "1"
},
{
"input": "999999999999 10000000007 100 100",
"output": "70100"
},
{
"input": "10000000001 2 1 1",
"output": "1"
},
{
"input": "29 6 1 2",
"output": "1"
},
{
"input": "99999999999 6 100 100",
"output": "300"
},
{
"input": "1000000000000 7 3 8",
"output": "8"
},
{
"input": "99999999999 2 1 1",
"output": "1"
},
{
"input": "1 2 1 1",
"output": "1"
},
{
"input": "999999999999 2 1 1",
"output": "1"
},
{
"input": "9 2 1 1",
"output": "1"
},
{
"input": "17 4 5 5",
"output": "5"
},
{
"input": "100000000000 3 1 1",
"output": "1"
},
{
"input": "100 7 1 1",
"output": "2"
},
{
"input": "1000000000000 3 100 100",
"output": "100"
},
{
"input": "70 3 10 10",
"output": "10"
},
{
"input": "1 2 5 1",
"output": "1"
},
{
"input": "1000000000000 3 1 1",
"output": "1"
},
{
"input": "804289377 846930887 78 16",
"output": "3326037780"
},
{
"input": "1000000000000 9 55 55",
"output": "55"
},
{
"input": "957747787 424238336 87 93",
"output": "10162213695"
},
{
"input": "25 6 1 2",
"output": "2"
},
{
"input": "22 7 3 8",
"output": "8"
},
{
"input": "10000000000 1 1 1",
"output": "0"
},
{
"input": "999999999999 2 10 10",
"output": "10"
},
{
"input": "999999999999 2 100 100",
"output": "100"
},
{
"input": "100 3 3 8",
"output": "6"
},
{
"input": "99999 2 1 1",
"output": "1"
},
{
"input": "100 3 2 5",
"output": "4"
},
{
"input": "1000000000000 13 10 17",
"output": "17"
},
{
"input": "7 2 1 2",
"output": "1"
},
{
"input": "10 3 1 2",
"output": "2"
},
{
"input": "5 2 2 2",
"output": "2"
},
{
"input": "100 3 5 2",
"output": "2"
},
{
"input": "7 2 1 1",
"output": "1"
},
{
"input": "70 4 1 1",
"output": "2"
},
{
"input": "10 4 1 1",
"output": "2"
},
{
"input": "6 7 41 42",
"output": "41"
},
{
"input": "10 3 10 1",
"output": "1"
},
{
"input": "5 5 2 3",
"output": "0"
},
{
"input": "1000000000000 3 99 99",
"output": "99"
},
{
"input": "7 3 100 1",
"output": "1"
},
{
"input": "7 2 100 5",
"output": "5"
},
{
"input": "1000000000000 1 23 33",
"output": "0"
},
{
"input": "30 7 1 1",
"output": "2"
},
{
"input": "100 3 1 1",
"output": "1"
},
{
"input": "90001 300 100 1",
"output": "1"
},
{
"input": "13 4 1 2",
"output": "2"
},
{
"input": "1000000000000 6 1 3",
"output": "2"
},
{
"input": "50 4 5 100",
"output": "10"
},
{
"input": "999 2 1 1",
"output": "1"
},
{
"input": "5 2 5 5",
"output": "5"
},
{
"input": "20 3 3 3",
"output": "3"
},
{
"input": "3982258181 1589052704 87 20",
"output": "16083055460"
},
{
"input": "100 3 1 3",
"output": "2"
},
{
"input": "7 3 1 1",
"output": "1"
},
{
"input": "19 10 100 100",
"output": "100"
},
{
"input": "23 3 100 1",
"output": "2"
},
{
"input": "25 7 100 1",
"output": "4"
},
{
"input": "100 9 1 2",
"output": "2"
},
{
"input": "9999999999 2 1 100",
"output": "1"
},
{
"input": "1000000000000 2 1 1",
"output": "0"
},
{
"input": "10000 3 1 1",
"output": "1"
},
{
"input": "22 7 1 6",
"output": "6"
},
{
"input": "100000000000 1 1 1",
"output": "0"
},
{
"input": "18 7 100 1",
"output": "4"
},
{
"input": "10003 4 1 100",
"output": "1"
},
{
"input": "3205261341 718648876 58 11",
"output": "3637324207"
},
{
"input": "8 3 100 1",
"output": "2"
},
{
"input": "15 7 1 1",
"output": "1"
},
{
"input": "1000000000000 1 20 20",
"output": "0"
},
{
"input": "16 7 3 2",
"output": "4"
},
{
"input": "1000000000000 1 1 1",
"output": "0"
},
{
"input": "7 3 1 100",
"output": "2"
},
{
"input": "16 3 1 100",
"output": "2"
},
{
"input": "13 4 1 10",
"output": "3"
},
{
"input": "10 4 5 5",
"output": "10"
},
{
"input": "14 3 1 100",
"output": "1"
},
{
"input": "100 33 100 1",
"output": "1"
},
{
"input": "22 7 1 8",
"output": "6"
},
{
"input": "10 4 2 1",
"output": "2"
},
{
"input": "6 4 2 2",
"output": "4"
},
{
"input": "17 4 2 1",
"output": "1"
},
{
"input": "7 3 100 10",
"output": "10"
},
{
"input": "702 7 3 2",
"output": "4"
},
{
"input": "8 3 1 5",
"output": "1"
},
{
"input": "3 2 5 2",
"output": "2"
},
{
"input": "99 19 1 7",
"output": "15"
},
{
"input": "16 3 100 1",
"output": "1"
},
{
"input": "100 34 1 100",
"output": "2"
},
{
"input": "100 33 1 1",
"output": "1"
},
{
"input": "2 3 4 3",
"output": "4"
},
{
"input": "15 4 4 10",
"output": "4"
},
{
"input": "1144108931 470211273 45 79",
"output": "11993619960"
},
{
"input": "2 3 3 4",
"output": "3"
},
{
"input": "29 5 4 9",
"output": "4"
},
{
"input": "15 7 1 5",
"output": "5"
},
{
"input": "1 1 1 1",
"output": "0"
},
{
"input": "1 1 3 4",
"output": "0"
},
{
"input": "10 12 2 1",
"output": "4"
},
{
"input": "1 2 3 4",
"output": "3"
}
] | 1,601,056,156
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 109
| 140
| 0
|
n,m,a,b=map(int,input().split())
if n%m:print(min((m*(n//m+1)-n)*a,(n%m)*b))
else:print(0)
|
Title: Commentary Boxes
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Berland Football Cup starts really soon! Commentators from all over the world come to the event.
Organizers have already built $n$ commentary boxes. $m$ regional delegations will come to the Cup. Every delegation should get the same number of the commentary boxes. If any box is left unoccupied then the delegations will be upset. So each box should be occupied by exactly one delegation.
If $n$ is not divisible by $m$, it is impossible to distribute the boxes to the delegations at the moment.
Organizers can build a new commentary box paying $a$ burles and demolish a commentary box paying $b$ burles. They can both build and demolish boxes arbitrary number of times (each time paying a corresponding fee). It is allowed to demolish all the existing boxes.
What is the minimal amount of burles organizers should pay to satisfy all the delegations (i.e. to make the number of the boxes be divisible by $m$)?
Input Specification:
The only line contains four integer numbers $n$, $m$, $a$ and $b$ ($1 \le n, m \le 10^{12}$, $1 \le a, b \le 100$), where $n$ is the initial number of the commentary boxes, $m$ is the number of delegations to come, $a$ is the fee to build a box and $b$ is the fee to demolish a box.
Output Specification:
Output the minimal amount of burles organizers should pay to satisfy all the delegations (i.e. to make the number of the boxes be divisible by $m$). It is allowed that the final number of the boxes is equal to $0$.
Demo Input:
['9 7 3 8\n', '2 7 3 7\n', '30 6 17 19\n']
Demo Output:
['15\n', '14\n', '0\n']
Note:
In the first example organizers can build $5$ boxes to make the total of $14$ paying $3$ burles for the each of them.
In the second example organizers can demolish $2$ boxes to make the total of $0$ paying $7$ burles for the each of them.
In the third example organizers are already able to distribute all the boxes equally among the delegations, each one get $5$ boxes.
|
```python
n,m,a,b=map(int,input().split())
if n%m:print(min((m*(n//m+1)-n)*a,(n%m)*b))
else:print(0)
```
| 3
|
|
1,008
|
A
|
Romaji
|
PROGRAMMING
| 900
|
[
"implementation",
"strings"
] | null | null |
Vitya has just started learning Berlanese language. It is known that Berlanese uses the Latin alphabet. Vowel letters are "a", "o", "u", "i", and "e". Other letters are consonant.
In Berlanese, there has to be a vowel after every consonant, but there can be any letter after any vowel. The only exception is a consonant "n"; after this letter, there can be any letter (not only a vowel) or there can be no letter at all. For example, the words "harakiri", "yupie", "man", and "nbo" are Berlanese while the words "horse", "king", "my", and "nz" are not.
Help Vitya find out if a word $s$ is Berlanese.
|
The first line of the input contains the string $s$ consisting of $|s|$ ($1\leq |s|\leq 100$) lowercase Latin letters.
|
Print "YES" (without quotes) if there is a vowel after every consonant except "n", otherwise print "NO".
You can print each letter in any case (upper or lower).
|
[
"sumimasen\n",
"ninja\n",
"codeforces\n"
] |
[
"YES\n",
"YES\n",
"NO\n"
] |
In the first and second samples, a vowel goes after each consonant except "n", so the word is Berlanese.
In the third sample, the consonant "c" goes after the consonant "r", and the consonant "s" stands on the end, so the word is not Berlanese.
| 500
|
[
{
"input": "sumimasen",
"output": "YES"
},
{
"input": "ninja",
"output": "YES"
},
{
"input": "codeforces",
"output": "NO"
},
{
"input": "auuaoonntanonnuewannnnpuuinniwoonennyolonnnvienonpoujinndinunnenannmuveoiuuhikucuziuhunnnmunzancenen",
"output": "YES"
},
{
"input": "n",
"output": "YES"
},
{
"input": "necnei",
"output": "NO"
},
{
"input": "nternn",
"output": "NO"
},
{
"input": "aucunuohja",
"output": "NO"
},
{
"input": "a",
"output": "YES"
},
{
"input": "b",
"output": "NO"
},
{
"input": "nn",
"output": "YES"
},
{
"input": "nnnzaaa",
"output": "YES"
},
{
"input": "zn",
"output": "NO"
},
{
"input": "ab",
"output": "NO"
},
{
"input": "aaaaaaaaaa",
"output": "YES"
},
{
"input": "aaaaaaaaab",
"output": "NO"
},
{
"input": "aaaaaaaaan",
"output": "YES"
},
{
"input": "baaaaaaaaa",
"output": "YES"
},
{
"input": "naaaaaaaaa",
"output": "YES"
},
{
"input": "nbaaaaaaaa",
"output": "YES"
},
{
"input": "bbaaaaaaaa",
"output": "NO"
},
{
"input": "bnaaaaaaaa",
"output": "NO"
},
{
"input": "eonwonojannonnufimiiniewuqaienokacevecinfuqihatenhunliquuyebayiaenifuexuanenuaounnboancaeowonu",
"output": "YES"
},
{
"input": "uixinnepnlinqaingieianndeakuniooudidonnnqeaituioeneiroionxuowudiooonayenfeonuino",
"output": "NO"
},
{
"input": "nnnnnyigaveteononnnnxaalenxuiiwannntoxonyoqonlejuoxuoconnnentoinnul",
"output": "NO"
},
{
"input": "ndonneasoiunhomuunnhuitonnntunntoanerekonoupunanuauenu",
"output": "YES"
},
{
"input": "anujemogawautiedoneobninnibonuunaoennnyoorufonxionntinimiboonununnnnnleenqunminzayoutanlalo",
"output": "NO"
},
{
"input": "y",
"output": "NO"
},
{
"input": "by",
"output": "NO"
},
{
"input": "yy",
"output": "NO"
},
{
"input": "nbn",
"output": "NO"
},
{
"input": "nz",
"output": "NO"
},
{
"input": "king",
"output": "NO"
},
{
"input": "g",
"output": "NO"
},
{
"input": "az",
"output": "NO"
},
{
"input": "x",
"output": "NO"
},
{
"input": "z",
"output": "NO"
},
{
"input": "yn",
"output": "NO"
},
{
"input": "aeo",
"output": "YES"
},
{
"input": "nb",
"output": "NO"
},
{
"input": "npn",
"output": "NO"
},
{
"input": "kini",
"output": "YES"
},
{
"input": "pya",
"output": "NO"
},
{
"input": "m",
"output": "NO"
},
{
"input": "p",
"output": "NO"
},
{
"input": "aaaaaaaak",
"output": "NO"
},
{
"input": "aab",
"output": "NO"
},
{
"input": "d",
"output": "NO"
},
{
"input": "at",
"output": "NO"
},
{
"input": "aaaaaak",
"output": "NO"
},
{
"input": "aaz",
"output": "NO"
},
{
"input": "aaab",
"output": "NO"
},
{
"input": "s",
"output": "NO"
},
{
"input": "nzzen",
"output": "NO"
},
{
"input": "aeionnhhhn",
"output": "NO"
},
{
"input": "h",
"output": "NO"
},
{
"input": "ny",
"output": "NO"
}
] | 1,638,017,871
| 2,147,483,647
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 0
| 31
| 0
|
s=input()
t=input()
ls=len(s)
lt=len(t)
v=['a','e','i','o','u']
c=0
if ls!=lt:
print('no')
else:
for i in range(len(s)):
if s[i] in v and t[i] in v or s[i] not in v and t[i] not in v:
c+=1
if c==ls:
print('Yes')
else:
print('No')
|
Title: Romaji
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vitya has just started learning Berlanese language. It is known that Berlanese uses the Latin alphabet. Vowel letters are "a", "o", "u", "i", and "e". Other letters are consonant.
In Berlanese, there has to be a vowel after every consonant, but there can be any letter after any vowel. The only exception is a consonant "n"; after this letter, there can be any letter (not only a vowel) or there can be no letter at all. For example, the words "harakiri", "yupie", "man", and "nbo" are Berlanese while the words "horse", "king", "my", and "nz" are not.
Help Vitya find out if a word $s$ is Berlanese.
Input Specification:
The first line of the input contains the string $s$ consisting of $|s|$ ($1\leq |s|\leq 100$) lowercase Latin letters.
Output Specification:
Print "YES" (without quotes) if there is a vowel after every consonant except "n", otherwise print "NO".
You can print each letter in any case (upper or lower).
Demo Input:
['sumimasen\n', 'ninja\n', 'codeforces\n']
Demo Output:
['YES\n', 'YES\n', 'NO\n']
Note:
In the first and second samples, a vowel goes after each consonant except "n", so the word is Berlanese.
In the third sample, the consonant "c" goes after the consonant "r", and the consonant "s" stands on the end, so the word is not Berlanese.
|
```python
s=input()
t=input()
ls=len(s)
lt=len(t)
v=['a','e','i','o','u']
c=0
if ls!=lt:
print('no')
else:
for i in range(len(s)):
if s[i] in v and t[i] in v or s[i] not in v and t[i] not in v:
c+=1
if c==ls:
print('Yes')
else:
print('No')
```
| -1
|
|
182
|
D
|
Common Divisors
|
PROGRAMMING
| 1,400
|
[
"brute force",
"hashing",
"implementation",
"math",
"strings"
] | null | null |
Vasya has recently learned at school what a number's divisor is and decided to determine a string's divisor. Here is what he came up with.
String *a* is the divisor of string *b* if and only if there exists a positive integer *x* such that if we write out string *a* consecutively *x* times, we get string *b*. For example, string "abab" has two divisors — "ab" and "abab".
Now Vasya wants to write a program that calculates the number of common divisors of two strings. Please help him.
|
The first input line contains a non-empty string *s*1.
The second input line contains a non-empty string *s*2.
Lengths of strings *s*1 and *s*2 are positive and do not exceed 105. The strings only consist of lowercase Latin letters.
|
Print the number of common divisors of strings *s*1 and *s*2.
|
[
"abcdabcd\nabcdabcdabcdabcd\n",
"aaa\naa\n"
] |
[
"2\n",
"1\n"
] |
In first sample the common divisors are strings "abcd" and "abcdabcd".
In the second sample the common divisor is a single string "a". String "aa" isn't included in the answer as it isn't a divisor of string "aaa".
| 1,000
|
[
{
"input": "abcdabcd\nabcdabcdabcdabcd",
"output": "2"
},
{
"input": "aaa\naa",
"output": "1"
},
{
"input": "aaaaaaaaaaaaaaaaaaaaaaaaa\naaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "3"
},
{
"input": "aaaaaaaaaaaaaa\naaaaaaaaaaaaaa",
"output": "4"
},
{
"input": "a\nb",
"output": "0"
},
{
"input": "a\na",
"output": "1"
},
{
"input": "ab\nac",
"output": "0"
},
{
"input": "asdkjjaskldjklasjdhasjdasdas\nasdjahsgdjslkdaygsudhasdkasnjdbayusvduasdklmaklsd",
"output": "0"
},
{
"input": "aaa\naaaaab",
"output": "0"
},
{
"input": "ab\naa",
"output": "0"
},
{
"input": "aa\naac",
"output": "0"
},
{
"input": "aba\nabaaba",
"output": "1"
},
{
"input": "aa\nbb",
"output": "0"
},
{
"input": "abababab\ncdcdcdcd",
"output": "0"
},
{
"input": "ab\nab",
"output": "1"
},
{
"input": "abcabcabc\nertert",
"output": "0"
},
{
"input": "aaaa\nbbbb",
"output": "0"
},
{
"input": "abc\ncde",
"output": "0"
},
{
"input": "abc\nabcabcab",
"output": "0"
},
{
"input": "aba\naaa",
"output": "0"
},
{
"input": "abcabc\nabdabdabd",
"output": "0"
},
{
"input": "aaaaaa\naaaaaaaaa",
"output": "2"
},
{
"input": "aaa\nbbb",
"output": "0"
}
] | 1,584,629,110
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 2
| 654
| 3,072,000
|
S1=input()
S2=input()
List=[]
Length_1 = len(S1)
Length_2 = len(S2)
K = min(Length_1,Length_2)
i = 1
while i*i <=K:
if K%i ==0:
List.append(i)
if i!=K/i:
List.append(K/i)
i+=1
Counter=0
for i in range(len(List)):
if Length_1%List[i]==0 and Length_2%List[i]==0:
Flag = True
a=0
b=0
while a < Length_1:
if b == List[i]:
b = 0
if S1[a]!=S1[b]:
Flag=False
break
a+=1
b+=1
if Flag:
A =0
B=0
while A<Length_2:
if B == List[i]:
B =0
if S2[A]!=S1[B]:
Flag = False
break
A+=1
B+=1
if Flag:
Counter+=1
print(Counter)
|
Title: Common Divisors
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya has recently learned at school what a number's divisor is and decided to determine a string's divisor. Here is what he came up with.
String *a* is the divisor of string *b* if and only if there exists a positive integer *x* such that if we write out string *a* consecutively *x* times, we get string *b*. For example, string "abab" has two divisors — "ab" and "abab".
Now Vasya wants to write a program that calculates the number of common divisors of two strings. Please help him.
Input Specification:
The first input line contains a non-empty string *s*1.
The second input line contains a non-empty string *s*2.
Lengths of strings *s*1 and *s*2 are positive and do not exceed 105. The strings only consist of lowercase Latin letters.
Output Specification:
Print the number of common divisors of strings *s*1 and *s*2.
Demo Input:
['abcdabcd\nabcdabcdabcdabcd\n', 'aaa\naa\n']
Demo Output:
['2\n', '1\n']
Note:
In first sample the common divisors are strings "abcd" and "abcdabcd".
In the second sample the common divisor is a single string "a". String "aa" isn't included in the answer as it isn't a divisor of string "aaa".
|
```python
S1=input()
S2=input()
List=[]
Length_1 = len(S1)
Length_2 = len(S2)
K = min(Length_1,Length_2)
i = 1
while i*i <=K:
if K%i ==0:
List.append(i)
if i!=K/i:
List.append(K/i)
i+=1
Counter=0
for i in range(len(List)):
if Length_1%List[i]==0 and Length_2%List[i]==0:
Flag = True
a=0
b=0
while a < Length_1:
if b == List[i]:
b = 0
if S1[a]!=S1[b]:
Flag=False
break
a+=1
b+=1
if Flag:
A =0
B=0
while A<Length_2:
if B == List[i]:
B =0
if S2[A]!=S1[B]:
Flag = False
break
A+=1
B+=1
if Flag:
Counter+=1
print(Counter)
```
| 0
|
|
126
|
B
|
Password
|
PROGRAMMING
| 1,700
|
[
"binary search",
"dp",
"hashing",
"string suffix structures",
"strings"
] | null | null |
Asterix, Obelix and their temporary buddies Suffix and Prefix has finally found the Harmony temple. However, its doors were firmly locked and even Obelix had no luck opening them.
A little later they found a string *s*, carved on a rock below the temple's gates. Asterix supposed that that's the password that opens the temple and read the string aloud. However, nothing happened. Then Asterix supposed that a password is some substring *t* of the string *s*.
Prefix supposed that the substring *t* is the beginning of the string *s*; Suffix supposed that the substring *t* should be the end of the string *s*; and Obelix supposed that *t* should be located somewhere inside the string *s*, that is, *t* is neither its beginning, nor its end.
Asterix chose the substring *t* so as to please all his companions. Besides, from all acceptable variants Asterix chose the longest one (as Asterix loves long strings). When Asterix read the substring *t* aloud, the temple doors opened.
You know the string *s*. Find the substring *t* or determine that such substring does not exist and all that's been written above is just a nice legend.
|
You are given the string *s* whose length can vary from 1 to 106 (inclusive), consisting of small Latin letters.
|
Print the string *t*. If a suitable *t* string does not exist, then print "Just a legend" without the quotes.
|
[
"fixprefixsuffix\n",
"abcdabc\n"
] |
[
"fix",
"Just a legend"
] |
none
| 1,000
|
[
{
"input": "fixprefixsuffix",
"output": "fix"
},
{
"input": "abcdabc",
"output": "Just a legend"
},
{
"input": "qwertyqwertyqwerty",
"output": "qwerty"
},
{
"input": "papapapap",
"output": "papap"
},
{
"input": "aaaaaaaaaa",
"output": "aaaaaaaa"
},
{
"input": "ghbdtn",
"output": "Just a legend"
},
{
"input": "a",
"output": "Just a legend"
},
{
"input": "aa",
"output": "Just a legend"
},
{
"input": "ab",
"output": "Just a legend"
},
{
"input": "aaa",
"output": "a"
},
{
"input": "aba",
"output": "Just a legend"
},
{
"input": "aab",
"output": "Just a legend"
},
{
"input": "abb",
"output": "Just a legend"
},
{
"input": "abc",
"output": "Just a legend"
},
{
"input": "aaabaabaaaaab",
"output": "Just a legend"
},
{
"input": "aabaaabaaaaab",
"output": "aab"
},
{
"input": "aaabaaaabab",
"output": "Just a legend"
},
{
"input": "abcabcabcabcabc",
"output": "abcabcabc"
},
{
"input": "aaaaabaaaa",
"output": "aaaa"
},
{
"input": "aaaabaaaaaaa",
"output": "aaaa"
},
{
"input": "ghghghgxghghghg",
"output": "ghghg"
},
{
"input": "kincenvizh",
"output": "Just a legend"
},
{
"input": "amcksgurlgqzqizdauqminfzshiweejkevbazyzylrrghumnvqeqqdedyopgtvxakqwpvxntxgrkrcxabhrgoxngrwrxrvcguuyw",
"output": "Just a legend"
},
{
"input": "kwuaizneqxfflhmyruotjlkqksinoanvkyvqptkkntnpjdyzicceelgooajdgpkneuhyvhdtmasiglplajxolxovlhkwuaizneqx",
"output": "Just a legend"
},
{
"input": "nfbdzgdlbjhrlvfryyjbvtsmzacxglcvukmyexdgpuiwvqbnfbdzgdlbjhrlvfryyjbtuomcwbwvlhefnfbdzgdlbjhrlvfryyjb",
"output": "nfbdzgdlbjhrlvfryyjb"
},
{
"input": "btbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgpmvbxbyszdugvmoyjeeqsywcvuqskcjotyhvdijyslgfvyujxthngnonasgnbzzygyikheelirdfsvuicbiazfdeqecbtbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgpccdtdteohtjjuicfjfcbzpynlqhecyqqrjpmexgfqywnfmusldgzvgnzdmuuujtkdfnlytzgstquwqpuccxbtbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgp",
"output": "btbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgp"
},
{
"input": "abcazabca",
"output": "a"
}
] | 1,653,271,859
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 97
| 404
| 17,305,600
|
s = input()
n = len(s)
p = [0] * (n + 1)
i, j = 0, 1
while j < n:
if s[j] == s[i]:
j += 1
i += 1
p[j] = i
elif i:
i = p[i]
else:
j += 1
a = p.pop()
b = p[a]
print(s[:a]
if a and a in p
else s[:b] if b else 'Just a legend'
)
|
Title: Password
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Asterix, Obelix and their temporary buddies Suffix and Prefix has finally found the Harmony temple. However, its doors were firmly locked and even Obelix had no luck opening them.
A little later they found a string *s*, carved on a rock below the temple's gates. Asterix supposed that that's the password that opens the temple and read the string aloud. However, nothing happened. Then Asterix supposed that a password is some substring *t* of the string *s*.
Prefix supposed that the substring *t* is the beginning of the string *s*; Suffix supposed that the substring *t* should be the end of the string *s*; and Obelix supposed that *t* should be located somewhere inside the string *s*, that is, *t* is neither its beginning, nor its end.
Asterix chose the substring *t* so as to please all his companions. Besides, from all acceptable variants Asterix chose the longest one (as Asterix loves long strings). When Asterix read the substring *t* aloud, the temple doors opened.
You know the string *s*. Find the substring *t* or determine that such substring does not exist and all that's been written above is just a nice legend.
Input Specification:
You are given the string *s* whose length can vary from 1 to 106 (inclusive), consisting of small Latin letters.
Output Specification:
Print the string *t*. If a suitable *t* string does not exist, then print "Just a legend" without the quotes.
Demo Input:
['fixprefixsuffix\n', 'abcdabc\n']
Demo Output:
['fix', 'Just a legend']
Note:
none
|
```python
s = input()
n = len(s)
p = [0] * (n + 1)
i, j = 0, 1
while j < n:
if s[j] == s[i]:
j += 1
i += 1
p[j] = i
elif i:
i = p[i]
else:
j += 1
a = p.pop()
b = p[a]
print(s[:a]
if a and a in p
else s[:b] if b else 'Just a legend'
)
```
| 3
|
|
822
|
A
|
I'm bored with life
|
PROGRAMMING
| 800
|
[
"implementation",
"math",
"number theory"
] | null | null |
Holidays have finished. Thanks to the help of the hacker Leha, Noora managed to enter the university of her dreams which is located in a town Pavlopolis. It's well known that universities provide students with dormitory for the period of university studies. Consequently Noora had to leave Vičkopolis and move to Pavlopolis. Thus Leha was left completely alone in a quiet town Vičkopolis. He almost even fell into a depression from boredom!
Leha came up with a task for himself to relax a little. He chooses two integers *A* and *B* and then calculates the greatest common divisor of integers "*A* factorial" and "*B* factorial". Formally the hacker wants to find out GCD(*A*!,<=*B*!). It's well known that the factorial of an integer *x* is a product of all positive integers less than or equal to *x*. Thus *x*!<==<=1·2·3·...·(*x*<=-<=1)·*x*. For example 4!<==<=1·2·3·4<==<=24. Recall that GCD(*x*,<=*y*) is the largest positive integer *q* that divides (without a remainder) both *x* and *y*.
Leha has learned how to solve this task very effective. You are able to cope with it not worse, aren't you?
|
The first and single line contains two integers *A* and *B* (1<=≤<=*A*,<=*B*<=≤<=109,<=*min*(*A*,<=*B*)<=≤<=12).
|
Print a single integer denoting the greatest common divisor of integers *A*! and *B*!.
|
[
"4 3\n"
] |
[
"6\n"
] |
Consider the sample.
4! = 1·2·3·4 = 24. 3! = 1·2·3 = 6. The greatest common divisor of integers 24 and 6 is exactly 6.
| 500
|
[
{
"input": "4 3",
"output": "6"
},
{
"input": "10 399603090",
"output": "3628800"
},
{
"input": "6 973151934",
"output": "720"
},
{
"input": "2 841668075",
"output": "2"
},
{
"input": "7 415216919",
"output": "5040"
},
{
"input": "3 283733059",
"output": "6"
},
{
"input": "11 562314608",
"output": "39916800"
},
{
"input": "3 990639260",
"output": "6"
},
{
"input": "11 859155400",
"output": "39916800"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "5 3",
"output": "6"
},
{
"input": "1 4",
"output": "1"
},
{
"input": "5 4",
"output": "24"
},
{
"input": "1 12",
"output": "1"
},
{
"input": "9 7",
"output": "5040"
},
{
"input": "2 3",
"output": "2"
},
{
"input": "6 11",
"output": "720"
},
{
"input": "6 7",
"output": "720"
},
{
"input": "11 11",
"output": "39916800"
},
{
"input": "4 999832660",
"output": "24"
},
{
"input": "7 999228288",
"output": "5040"
},
{
"input": "11 999257105",
"output": "39916800"
},
{
"input": "11 999286606",
"output": "39916800"
},
{
"input": "3 999279109",
"output": "6"
},
{
"input": "999632727 11",
"output": "39916800"
},
{
"input": "999625230 7",
"output": "5040"
},
{
"input": "999617047 3",
"output": "6"
},
{
"input": "999646548 7",
"output": "5040"
},
{
"input": "999639051 3",
"output": "6"
},
{
"input": "12 12",
"output": "479001600"
},
{
"input": "12 1",
"output": "1"
},
{
"input": "1213 5",
"output": "120"
},
{
"input": "8 9",
"output": "40320"
},
{
"input": "12 9",
"output": "362880"
},
{
"input": "12 1000000000",
"output": "479001600"
},
{
"input": "1000000000 1",
"output": "1"
},
{
"input": "12 13",
"output": "479001600"
},
{
"input": "2 29845",
"output": "2"
},
{
"input": "10 21",
"output": "3628800"
},
{
"input": "12 20",
"output": "479001600"
},
{
"input": "15 12",
"output": "479001600"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "1000000000 12",
"output": "479001600"
},
{
"input": "11 30",
"output": "39916800"
},
{
"input": "17 12",
"output": "479001600"
},
{
"input": "4 19",
"output": "24"
},
{
"input": "12 15",
"output": "479001600"
},
{
"input": "20 6",
"output": "720"
},
{
"input": "10 20",
"output": "3628800"
},
{
"input": "10 10",
"output": "3628800"
},
{
"input": "22 12",
"output": "479001600"
},
{
"input": "20 12",
"output": "479001600"
},
{
"input": "12 23",
"output": "479001600"
},
{
"input": "12 22",
"output": "479001600"
},
{
"input": "18 3",
"output": "6"
},
{
"input": "14 10",
"output": "3628800"
},
{
"input": "14 12",
"output": "479001600"
},
{
"input": "8 3",
"output": "6"
},
{
"input": "5 5",
"output": "120"
}
] | 1,642,604,488
| 2,147,483,647
|
PyPy 3-64
|
RUNTIME_ERROR
|
TESTS
| 1
| 217
| 3,584,000
|
def gt(n):
if n==1:
return 1
else:
return n*gt(n-1)
a,b = [gt(int(x)) for x in input().split()]
while(a*b):
if a>b:
a=a-b
else:
b=b-a
print(max(a,b))
|
Title: I'm bored with life
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Holidays have finished. Thanks to the help of the hacker Leha, Noora managed to enter the university of her dreams which is located in a town Pavlopolis. It's well known that universities provide students with dormitory for the period of university studies. Consequently Noora had to leave Vičkopolis and move to Pavlopolis. Thus Leha was left completely alone in a quiet town Vičkopolis. He almost even fell into a depression from boredom!
Leha came up with a task for himself to relax a little. He chooses two integers *A* and *B* and then calculates the greatest common divisor of integers "*A* factorial" and "*B* factorial". Formally the hacker wants to find out GCD(*A*!,<=*B*!). It's well known that the factorial of an integer *x* is a product of all positive integers less than or equal to *x*. Thus *x*!<==<=1·2·3·...·(*x*<=-<=1)·*x*. For example 4!<==<=1·2·3·4<==<=24. Recall that GCD(*x*,<=*y*) is the largest positive integer *q* that divides (without a remainder) both *x* and *y*.
Leha has learned how to solve this task very effective. You are able to cope with it not worse, aren't you?
Input Specification:
The first and single line contains two integers *A* and *B* (1<=≤<=*A*,<=*B*<=≤<=109,<=*min*(*A*,<=*B*)<=≤<=12).
Output Specification:
Print a single integer denoting the greatest common divisor of integers *A*! and *B*!.
Demo Input:
['4 3\n']
Demo Output:
['6\n']
Note:
Consider the sample.
4! = 1·2·3·4 = 24. 3! = 1·2·3 = 6. The greatest common divisor of integers 24 and 6 is exactly 6.
|
```python
def gt(n):
if n==1:
return 1
else:
return n*gt(n-1)
a,b = [gt(int(x)) for x in input().split()]
while(a*b):
if a>b:
a=a-b
else:
b=b-a
print(max(a,b))
```
| -1
|
|
386
|
A
|
Second-Price Auction
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
In this problem we consider a special type of an auction, which is called the second-price auction. As in regular auction *n* bidders place a bid which is price a bidder ready to pay. The auction is closed, that is, each bidder secretly informs the organizer of the auction price he is willing to pay. After that, the auction winner is the participant who offered the highest price. However, he pay not the price he offers, but the highest price among the offers of other participants (hence the name: the second-price auction).
Write a program that reads prices offered by bidders and finds the winner and the price he will pay. Consider that all of the offered prices are different.
|
The first line of the input contains *n* (2<=≤<=*n*<=≤<=1000) — number of bidders. The second line contains *n* distinct integer numbers *p*1,<=*p*2,<=... *p**n*, separated by single spaces (1<=≤<=*p**i*<=≤<=10000), where *p**i* stands for the price offered by the *i*-th bidder.
|
The single output line should contain two integers: index of the winner and the price he will pay. Indices are 1-based.
|
[
"2\n5 7\n",
"3\n10 2 8\n",
"6\n3 8 2 9 4 14\n"
] |
[
"2 5\n",
"1 8\n",
"6 9\n"
] |
none
| 500
|
[
{
"input": "2\n5 7",
"output": "2 5"
},
{
"input": "3\n10 2 8",
"output": "1 8"
},
{
"input": "6\n3 8 2 9 4 14",
"output": "6 9"
},
{
"input": "4\n4707 7586 4221 5842",
"output": "2 5842"
},
{
"input": "5\n3304 4227 4869 6937 6002",
"output": "4 6002"
},
{
"input": "6\n5083 3289 7708 5362 9031 7458",
"output": "5 7708"
},
{
"input": "7\n9038 6222 3392 1706 3778 1807 2657",
"output": "1 6222"
},
{
"input": "8\n7062 2194 4481 3864 7470 1814 8091 733",
"output": "7 7470"
},
{
"input": "9\n2678 5659 9199 2628 7906 7496 4524 2663 3408",
"output": "3 7906"
},
{
"input": "2\n3458 1504",
"output": "1 1504"
},
{
"input": "50\n9237 3904 407 9052 6657 9229 9752 3888 7732 2512 4614 1055 2355 7108 6506 6849 2529 8862 159 8630 7906 7941 960 8470 333 8659 54 9475 3163 5625 6393 6814 2656 3388 169 7918 4881 8468 9983 6281 6340 280 5108 2996 101 7617 3313 8172 326 1991",
"output": "39 9752"
},
{
"input": "100\n2515 3324 7975 6171 4240 1217 4829 5203 8603 6900 3031 4699 4732 6070 4221 3228 6497 7359 9130 4346 4619 1109 3945 5442 3271 16 9711 2045 6410 2301 3406 8125 6003 1892 1260 9661 3940 6692 4708 7027 4930 6925 1979 5361 4263 3144 867 8639 6230 5562 9714 3676 4231 3347 4733 4920 4881 3431 1059 7313 8912 3038 9308 72 9583 7009 3034 7425 2398 6141 3245 2495 2933 6710 8289 9806 1226 8393 7349 6462 1618 9613 3546 6012 2964 9995 1578 210 2123 4874 1252 8625 348 8020 803 7244 9080 5088 706 2602",
"output": "86 9806"
},
{
"input": "2\n2 1",
"output": "1 1"
},
{
"input": "2\n1 2",
"output": "2 1"
},
{
"input": "3\n10 20 30",
"output": "3 20"
},
{
"input": "3\n10 30 20",
"output": "2 20"
},
{
"input": "3\n20 10 30",
"output": "3 20"
},
{
"input": "3\n20 30 10",
"output": "2 20"
},
{
"input": "3\n30 10 20",
"output": "1 20"
},
{
"input": "3\n30 20 10",
"output": "1 20"
},
{
"input": "2\n1 10000",
"output": "2 1"
},
{
"input": "2\n10000 999",
"output": "1 999"
},
{
"input": "3\n3 4 1",
"output": "2 3"
},
{
"input": "6\n1 2 24 6 5 7",
"output": "3 7"
}
] | 1,642,798,455
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 42
| 46
| 0
|
n=int(input());
c=0
l=list(map(int,input().split()))
maxi=max(l)
for i in range(len(l)):
if l[i]==maxi:
m=i+1
break
p=sorted(l)
print(m,p[-2])
|
Title: Second-Price Auction
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
In this problem we consider a special type of an auction, which is called the second-price auction. As in regular auction *n* bidders place a bid which is price a bidder ready to pay. The auction is closed, that is, each bidder secretly informs the organizer of the auction price he is willing to pay. After that, the auction winner is the participant who offered the highest price. However, he pay not the price he offers, but the highest price among the offers of other participants (hence the name: the second-price auction).
Write a program that reads prices offered by bidders and finds the winner and the price he will pay. Consider that all of the offered prices are different.
Input Specification:
The first line of the input contains *n* (2<=≤<=*n*<=≤<=1000) — number of bidders. The second line contains *n* distinct integer numbers *p*1,<=*p*2,<=... *p**n*, separated by single spaces (1<=≤<=*p**i*<=≤<=10000), where *p**i* stands for the price offered by the *i*-th bidder.
Output Specification:
The single output line should contain two integers: index of the winner and the price he will pay. Indices are 1-based.
Demo Input:
['2\n5 7\n', '3\n10 2 8\n', '6\n3 8 2 9 4 14\n']
Demo Output:
['2 5\n', '1 8\n', '6 9\n']
Note:
none
|
```python
n=int(input());
c=0
l=list(map(int,input().split()))
maxi=max(l)
for i in range(len(l)):
if l[i]==maxi:
m=i+1
break
p=sorted(l)
print(m,p[-2])
```
| 3
|
|
141
|
A
|
Amusing Joke
|
PROGRAMMING
| 800
|
[
"implementation",
"sortings",
"strings"
] | null | null |
So, the New Year holidays are over. Santa Claus and his colleagues can take a rest and have guests at last. When two "New Year and Christmas Men" meet, thear assistants cut out of cardboard the letters from the guest's name and the host's name in honor of this event. Then the hung the letters above the main entrance. One night, when everyone went to bed, someone took all the letters of our characters' names. Then he may have shuffled the letters and put them in one pile in front of the door.
The next morning it was impossible to find the culprit who had made the disorder. But everybody wondered whether it is possible to restore the names of the host and his guests from the letters lying at the door? That is, we need to verify that there are no extra letters, and that nobody will need to cut more letters.
Help the "New Year and Christmas Men" and their friends to cope with this problem. You are given both inscriptions that hung over the front door the previous night, and a pile of letters that were found at the front door next morning.
|
The input file consists of three lines: the first line contains the guest's name, the second line contains the name of the residence host and the third line contains letters in a pile that were found at the door in the morning. All lines are not empty and contain only uppercase Latin letters. The length of each line does not exceed 100.
|
Print "YES" without the quotes, if the letters in the pile could be permuted to make the names of the "New Year and Christmas Men". Otherwise, print "NO" without the quotes.
|
[
"SANTACLAUS\nDEDMOROZ\nSANTAMOROZDEDCLAUS\n",
"PAPAINOEL\nJOULUPUKKI\nJOULNAPAOILELUPUKKI\n",
"BABBONATALE\nFATHERCHRISTMAS\nBABCHRISTMASBONATALLEFATHER\n"
] |
[
"YES\n",
"NO\n",
"NO\n"
] |
In the first sample the letters written in the last line can be used to write the names and there won't be any extra letters left.
In the second sample letter "P" is missing from the pile and there's an extra letter "L".
In the third sample there's an extra letter "L".
| 500
|
[
{
"input": "SANTACLAUS\nDEDMOROZ\nSANTAMOROZDEDCLAUS",
"output": "YES"
},
{
"input": "PAPAINOEL\nJOULUPUKKI\nJOULNAPAOILELUPUKKI",
"output": "NO"
},
{
"input": "BABBONATALE\nFATHERCHRISTMAS\nBABCHRISTMASBONATALLEFATHER",
"output": "NO"
},
{
"input": "B\nA\nAB",
"output": "YES"
},
{
"input": "ONDOL\nJNPB\nONLNJBODP",
"output": "YES"
},
{
"input": "Y\nW\nYW",
"output": "YES"
},
{
"input": "OI\nM\nIMO",
"output": "YES"
},
{
"input": "VFQRWWWACX\nGHZJPOQUSXRAQDGOGMR\nOPAWDOUSGWWCGQXXQAZJRQRGHRMVF",
"output": "YES"
},
{
"input": "JUTCN\nPIGMZOPMEUFADQBW\nNWQGZMAIPUPOMCDUB",
"output": "NO"
},
{
"input": "Z\nO\nZOCNDOLTBZKQLTBOLDEGXRHZGTTPBJBLSJCVSVXISQZCSFDEBXRCSGBGTHWOVIXYHACAGBRYBKBJAEPIQZHVEGLYH",
"output": "NO"
},
{
"input": "IQ\nOQ\nQOQIGGKFNHJSGCGM",
"output": "NO"
},
{
"input": "ROUWANOPNIGTVMIITVMZ\nOQTUPZMTKUGY\nVTVNGZITGPUNPMQOOATUUIYIWMMKZOTR",
"output": "YES"
},
{
"input": "OVQELLOGFIOLEHXMEMBJDIGBPGEYFG\nJNKFPFFIJOFHRIFHXEWYZOPDJBZTJZKBWQTECNHRFSJPJOAPQT\nYAIPFFFEXJJNEJPLREIGODEGQZVMCOBDFKWTMWJSBEBTOFFQOHIQJLHFNXIGOHEZRZLFOKJBJPTPHPGY",
"output": "YES"
},
{
"input": "NBJGVNGUISUXQTBOBKYHQCOOVQWUXWPXBUDLXPKX\nNSFQDFUMQDQWQ\nWXKKVNTDQQFXCUQBIMQGQHSLVGWSBFYBUPOWPBDUUJUXQNOQDNXOX",
"output": "YES"
},
{
"input": "IJHHGKCXWDBRWJUPRDBZJLNTTNWKXLUGJSBWBOAUKWRAQWGFNL\nNJMWRMBCNPHXTDQQNZ\nWDNJRCLILNQRHWBANLTXWMJBPKUPGKJDJZAQWKTZFBRCTXHHBNXRGUQUNBNMWODGSJWW",
"output": "YES"
},
{
"input": "SRROWANGUGZHCIEFYMQVTWVOMDWPUZJFRDUMVFHYNHNTTGNXCJ\nDJYWGLBFCCECXFHOLORDGDCNRHPWXNHXFCXQCEZUHRRNAEKUIX\nWCUJDNYHNHYOPWMHLDCDYRWBVOGHFFUKOZTXJRXJHRGWICCMRNEVNEGQWTZPNFCSHDRFCFQDCXMHTLUGZAXOFNXNVGUEXIACRERU",
"output": "YES"
},
{
"input": "H\nJKFGHMIAHNDBMFXWYQLZRSVNOTEGCQSVUBYUOZBTNKTXPFQDCMKAGFITEUGOYDFIYQIORMFJEOJDNTFVIQEBICSNGKOSNLNXJWC\nBQSVDOGIHCHXSYNYTQFCHNJGYFIXTSOQINZOKSVQJMTKNTGFNXAVTUYEONMBQMGJLEWJOFGEARIOPKFUFCEMUBRBDNIIDFZDCLWK",
"output": "YES"
},
{
"input": "DSWNZRFVXQ\nPVULCZGOOU\nUOLVZXNUPOQRZGWFVDSCANQTCLEIE",
"output": "NO"
},
{
"input": "EUHTSCENIPXLTSBMLFHD\nIZAVSZPDLXOAGESUSE\nLXAELAZ",
"output": "NO"
},
{
"input": "WYSJFEREGELSKRQRXDXCGBODEFZVSI\nPEJKMGFLBFFDWRCRFSHVEFLEBTJCVCHRJTLDTISHPOGFWPLEWNYJLMXWIAOTYOXMV\nHXERTZWLEXTPIOTFRVMEJVYFFJLRPFMXDEBNSGCEOFFCWTKIDDGCFYSJKGLHBORWEPLDRXRSJYBGASSVCMHEEJFLVI",
"output": "NO"
},
{
"input": "EPBMDIUQAAUGLBIETKOKFLMTCVEPETWJRHHYKCKU\nHGMAETVPCFZYNNKDQXVXUALHYLOTCHM\nECGXACVKEYMCEDOTMKAUFHLHOMT",
"output": "NO"
},
{
"input": "NUBKQEJHALANSHEIFUZHYEZKKDRFHQKAJHLAOWTZIMOCWOVVDW\nEFVOBIGAUAUSQGVSNBKNOBDMINODMFSHDL\nKLAMKNTHBFFOHVKWICHBKNDDQNEISODUSDNLUSIOAVWY",
"output": "NO"
},
{
"input": "VXINHOMEQCATZUGAJEIUIZZLPYFGUTVLNBNWCUVMEENUXKBWBGZTMRJJVJDLVSLBABVCEUDDSQFHOYPYQTWVAGTWOLKYISAGHBMC\nZMRGXPZSHOGCSAECAPGVOIGCWEOWWOJXLGYRDMPXBLOKZVRACPYQLEQGFQCVYXAGBEBELUTDAYEAGPFKXRULZCKFHZCHVCWIRGPK\nRCVUXGQVNWFGRUDLLENNDQEJHYYVWMKTLOVIPELKPWCLSQPTAXAYEMGWCBXEVAIZGGDDRBRT",
"output": "NO"
},
{
"input": "PHBDHHWUUTZAHELGSGGOPOQXSXEZIXHZTOKYFBQLBDYWPVCNQSXHEAXRRPVHFJBVBYCJIFOTQTWSUOWXLKMVJJBNLGTVITWTCZZ\nFUPDLNVIHRWTEEEHOOEC\nLOUSUUSZCHJBPEWIILUOXEXRQNCJEGTOBRVZLTTZAHTKVEJSNGHFTAYGY",
"output": "NO"
},
{
"input": "GDSLNIIKTO\nJF\nPDQYFKDTNOLI",
"output": "NO"
},
{
"input": "AHOKHEKKPJLJIIWJRCGY\nORELJCSIX\nZVWPXVFWFSWOXXLIHJKPXIOKRELYE",
"output": "NO"
},
{
"input": "ZWCOJFORBPHXCOVJIDPKVECMHVHCOC\nTEV\nJVGTBFTLFVIEPCCHODOFOMCVZHWXVCPEH",
"output": "NO"
},
{
"input": "AGFIGYWJLVMYZGNQHEHWKJIAWBPUAQFERMCDROFN\nPMJNHMVNRGCYZAVRWNDSMLSZHFNYIUWFPUSKKIGU\nMCDVPPRXGUAYLSDRHRURZASXUWZSIIEZCPXUVEONKNGNWRYGOSFMCKESMVJZHWWUCHWDQMLASLNNMHAU",
"output": "NO"
},
{
"input": "XLOWVFCZSSXCSYQTIIDKHNTKNKEEDFMDZKXSPVLBIDIREDUAIN\nZKIWNDGBISDB\nSLPKLYFYSRNRMOSWYLJJDGFFENPOXYLPZFTQDANKBDNZDIIEWSUTTKYBKVICLG",
"output": "NO"
},
{
"input": "PMUKBTRKFIAYVGBKHZHUSJYSSEPEOEWPOSPJLWLOCTUYZODLTUAFCMVKGQKRRUSOMPAYOTBTFPXYAZXLOADDEJBDLYOTXJCJYTHA\nTWRRAJLCQJTKOKWCGUH\nEWDPNXVCXWCDQCOYKKSOYTFSZTOOPKPRDKFJDETKSRAJRVCPDOBWUGPYRJPUWJYWCBLKOOTUPBESTOFXZHTYLLMCAXDYAEBUTAHM",
"output": "NO"
},
{
"input": "QMIMGQRQDMJDPNFEFXSXQMCHEJKTWCTCVZPUAYICOIRYOWKUSIWXJLHDYWSBOITHTMINXFKBKAWZTXXBJIVYCRWKXNKIYKLDDXL\nV\nFWACCXBVDOJFIUAVYRALBYJKXXWIIFORRUHKHCXLDBZMXIYJWISFEAWTIQFIZSBXMKNOCQKVKRWDNDAMQSTKYLDNYVTUCGOJXJTW",
"output": "NO"
},
{
"input": "XJXPVOOQODELPPWUISSYVVXRJTYBPDHJNENQEVQNVFIXSESKXVYPVVHPMOSX\nLEXOPFPVPSZK\nZVXVPYEYOYXVOISVLXPOVHEQVXPNQJIOPFDTXEUNMPEPPHELNXKKWSVSOXSBPSJDPVJVSRFQ",
"output": "YES"
},
{
"input": "OSKFHGYNQLSRFSAHPXKGPXUHXTRBJNAQRBSSWJVEENLJCDDHFXVCUNPZAIVVO\nFNUOCXAGRRHNDJAHVVLGGEZQHWARYHENBKHP\nUOEFNWVXCUNERLKVTHAGPSHKHDYFPYWZHJKHQLSNFBJHVJANRXCNSDUGVDABGHVAOVHBJZXGRACHRXEGNRPQEAPORQSILNXFS",
"output": "YES"
},
{
"input": "VYXYVVACMLPDHONBUTQFZTRREERBLKUJYKAHZRCTRLRCLOZYWVPBRGDQPFPQIF\nFE\nRNRPEVDRLYUQFYRZBCQLCYZEABKLRXCJLKVZBVFUEYRATOMDRTHFPGOWQVTIFPPH",
"output": "YES"
},
{
"input": "WYXUZQJQNLASEGLHPMSARWMTTQMQLVAZLGHPIZTRVTCXDXBOLNXZPOFCTEHCXBZ\nBLQZRRWP\nGIQZXPLTTMNHQVWPPEAPLOCDMBSTHRCFLCQRRZXLVAOQEGZBRUZJXXZTMAWLZHSLWNQTYXB",
"output": "YES"
},
{
"input": "MKVJTSSTDGKPVVDPYSRJJYEVGKBMSIOKHLZQAEWLRIBINVRDAJIBCEITKDHUCCVY\nPUJJQFHOGZKTAVNUGKQUHMKTNHCCTI\nQVJKUSIGTSVYUMOMLEGHWYKSKQTGATTKBNTKCJKJPCAIRJIRMHKBIZISEGFHVUVQZBDERJCVAKDLNTHUDCHONDCVVJIYPP",
"output": "YES"
},
{
"input": "OKNJOEYVMZXJMLVJHCSPLUCNYGTDASKSGKKCRVIDGEIBEWRVBVRVZZTLMCJLXHJIA\nDJBFVRTARTFZOWN\nAGHNVUNJVCPLWSVYBJKZSVTFGLELZASLWTIXDDJXCZDICTVIJOTMVEYOVRNMJGRKKHRMEBORAKFCZJBR",
"output": "YES"
},
{
"input": "OQZACLPSAGYDWHFXDFYFRRXWGIEJGSXWUONAFWNFXDTGVNDEWNQPHUXUJNZWWLBPYL\nOHBKWRFDRQUAFRCMT\nWIQRYXRJQWWRUWCYXNXALKFZGXFTLOODWRDPGURFUFUQOHPWBASZNVWXNCAGHWEHFYESJNFBMNFDDAPLDGT",
"output": "YES"
},
{
"input": "OVIRQRFQOOWVDEPLCJETWQSINIOPLTLXHSQWUYUJNFBMKDNOSHNJQQCDHZOJVPRYVSV\nMYYDQKOOYPOOUELCRIT\nNZSOTVLJTTVQLFHDQEJONEOUOFOLYVSOIYUDNOSIQVIRMVOERCLMYSHPCQKIDRDOQPCUPQBWWRYYOXJWJQPNKH",
"output": "YES"
},
{
"input": "WGMBZWNMSJXNGDUQUJTCNXDSJJLYRDOPEGPQXYUGBESDLFTJRZDDCAAFGCOCYCQMDBWK\nYOBMOVYTUATTFGJLYUQD\nDYXVTLQCYFJUNJTUXPUYOPCBCLBWNSDUJRJGWDOJDSQAAMUOJWSYERDYDXYTMTOTMQCGQZDCGNFBALGGDFKZMEBG",
"output": "YES"
},
{
"input": "CWLRBPMEZCXAPUUQFXCUHAQTLPBTXUUKWVXKBHKNSSJFEXLZMXGVFHHVTPYAQYTIKXJJE\nMUFOSEUEXEQTOVLGDSCWM\nJUKEQCXOXWEHCGKFPBIGMWVJLXUONFXBYTUAXERYTXKCESKLXAEHVPZMMUFTHLXTTZSDMBJLQPEUWCVUHSQQVUASPF",
"output": "YES"
},
{
"input": "IDQRX\nWETHO\nODPDGBHVUVSSISROHQJTUKPUCLXABIZQQPPBPKOSEWGEHRSRRNBAVLYEMZISMWWGKHVTXKUGUXEFBSWOIWUHRJGMWBMHQLDZHBWA",
"output": "NO"
},
{
"input": "IXFDY\nJRMOU\nDF",
"output": "NO"
},
{
"input": "JPSPZ\nUGCUB\nJMZZZZZZZZ",
"output": "NO"
},
{
"input": "AC\nA\nBBA",
"output": "NO"
},
{
"input": "UIKWWKXLSHTOOZOVGXKYSOJEHAUEEG\nKZXQDWJJWRXFHKJDQHJK\nXMZHTFOGEXAUJXXJUYVJIFOTKLZHDKELJWERHMGAWGKWAQKEKHIDWGGZVYOHKXRPWSJDPESFJUMKQYWBYUTHQYEFZUGKQOBHYDWB",
"output": "NO"
},
{
"input": "PXWRXRPFLR\nPJRWWXIVHODV\nXW",
"output": "NO"
},
{
"input": "CHTAZVHGSHCVIBK\nEQINEBKXEPYJSAZIMLDF\nZCZZZZDZMCZZEZDZZEZZZZQZZBZZZOZZCZE",
"output": "NO"
},
{
"input": "GXPZFSELJJNDAXYRV\nUYBKPMVBSOVOJWMONLTJOJCNQKMTAHEWLHOWIIBH\nHCWNFWJPEJIWOVPTBMVCRJLSISSVNOHCKLBFMIUAIMASQWPXEYXBOXQGFEMYJLBKDCZIMJNHOJEDGGANIVYKQTUOSOVOPWHVJGXH",
"output": "NO"
},
{
"input": "LFGJCJJDUTUP\nOVSBILTIYCJCRHKCIXCETJQJJ\nGIJJTJCLTJJJ",
"output": "NO"
},
{
"input": "GIO\nPRL\nPRL",
"output": "NO"
},
{
"input": "A\nB\nABC",
"output": "NO"
},
{
"input": "KKK\nKKK\nZZZZZ",
"output": "NO"
},
{
"input": "ZMYGQLDBLAPN\nZFJBKWHROVNPSJQUDFTHOCGREUFLYIWYICD\nZMJZZEDAZANKZZZZZZEZZBZDZZZZZZKHZZFZZZDZNZMDZZA",
"output": "NO"
}
] | 1,696,870,550
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 54
| 92
| 307,200
|
from collections import Counter
a=input()
b=input()
c=input()
x=Counter(a)
y=Counter(b)
z=Counter(c)
if x+y ==z:
print("YES")
else:
print("NO")
|
Title: Amusing Joke
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
So, the New Year holidays are over. Santa Claus and his colleagues can take a rest and have guests at last. When two "New Year and Christmas Men" meet, thear assistants cut out of cardboard the letters from the guest's name and the host's name in honor of this event. Then the hung the letters above the main entrance. One night, when everyone went to bed, someone took all the letters of our characters' names. Then he may have shuffled the letters and put them in one pile in front of the door.
The next morning it was impossible to find the culprit who had made the disorder. But everybody wondered whether it is possible to restore the names of the host and his guests from the letters lying at the door? That is, we need to verify that there are no extra letters, and that nobody will need to cut more letters.
Help the "New Year and Christmas Men" and their friends to cope with this problem. You are given both inscriptions that hung over the front door the previous night, and a pile of letters that were found at the front door next morning.
Input Specification:
The input file consists of three lines: the first line contains the guest's name, the second line contains the name of the residence host and the third line contains letters in a pile that were found at the door in the morning. All lines are not empty and contain only uppercase Latin letters. The length of each line does not exceed 100.
Output Specification:
Print "YES" without the quotes, if the letters in the pile could be permuted to make the names of the "New Year and Christmas Men". Otherwise, print "NO" without the quotes.
Demo Input:
['SANTACLAUS\nDEDMOROZ\nSANTAMOROZDEDCLAUS\n', 'PAPAINOEL\nJOULUPUKKI\nJOULNAPAOILELUPUKKI\n', 'BABBONATALE\nFATHERCHRISTMAS\nBABCHRISTMASBONATALLEFATHER\n']
Demo Output:
['YES\n', 'NO\n', 'NO\n']
Note:
In the first sample the letters written in the last line can be used to write the names and there won't be any extra letters left.
In the second sample letter "P" is missing from the pile and there's an extra letter "L".
In the third sample there's an extra letter "L".
|
```python
from collections import Counter
a=input()
b=input()
c=input()
x=Counter(a)
y=Counter(b)
z=Counter(c)
if x+y ==z:
print("YES")
else:
print("NO")
```
| 3
|
|
785
|
A
|
Anton and Polyhedrons
|
PROGRAMMING
| 800
|
[
"implementation",
"strings"
] | null | null |
Anton's favourite geometric figures are regular polyhedrons. Note that there are five kinds of regular polyhedrons:
- Tetrahedron. Tetrahedron has 4 triangular faces. - Cube. Cube has 6 square faces. - Octahedron. Octahedron has 8 triangular faces. - Dodecahedron. Dodecahedron has 12 pentagonal faces. - Icosahedron. Icosahedron has 20 triangular faces.
All five kinds of polyhedrons are shown on the picture below:
Anton has a collection of *n* polyhedrons. One day he decided to know, how many faces his polyhedrons have in total. Help Anton and find this number!
|
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=200<=000) — the number of polyhedrons in Anton's collection.
Each of the following *n* lines of the input contains a string *s**i* — the name of the *i*-th polyhedron in Anton's collection. The string can look like this:
- "Tetrahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is a tetrahedron. - "Cube" (without quotes), if the *i*-th polyhedron in Anton's collection is a cube. - "Octahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is an octahedron. - "Dodecahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is a dodecahedron. - "Icosahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is an icosahedron.
|
Output one number — the total number of faces in all the polyhedrons in Anton's collection.
|
[
"4\nIcosahedron\nCube\nTetrahedron\nDodecahedron\n",
"3\nDodecahedron\nOctahedron\nOctahedron\n"
] |
[
"42\n",
"28\n"
] |
In the first sample Anton has one icosahedron, one cube, one tetrahedron and one dodecahedron. Icosahedron has 20 faces, cube has 6 faces, tetrahedron has 4 faces and dodecahedron has 12 faces. In total, they have 20 + 6 + 4 + 12 = 42 faces.
| 500
|
[
{
"input": "4\nIcosahedron\nCube\nTetrahedron\nDodecahedron",
"output": "42"
},
{
"input": "3\nDodecahedron\nOctahedron\nOctahedron",
"output": "28"
},
{
"input": "25\nIcosahedron\nOctahedron\nTetrahedron\nDodecahedron\nCube\nIcosahedron\nOctahedron\nCube\nTetrahedron\nIcosahedron\nIcosahedron\nTetrahedron\nOctahedron\nDodecahedron\nIcosahedron\nOctahedron\nIcosahedron\nTetrahedron\nDodecahedron\nTetrahedron\nOctahedron\nCube\nCube\nDodecahedron\nTetrahedron",
"output": "256"
},
{
"input": "1\nTetrahedron",
"output": "4"
},
{
"input": "1\nCube",
"output": "6"
},
{
"input": "1\nOctahedron",
"output": "8"
},
{
"input": "1\nDodecahedron",
"output": "12"
},
{
"input": "1\nIcosahedron",
"output": "20"
},
{
"input": "28\nOctahedron\nDodecahedron\nOctahedron\nOctahedron\nDodecahedron\nIcosahedron\nIcosahedron\nDodecahedron\nDodecahedron\nDodecahedron\nCube\nDodecahedron\nCube\nTetrahedron\nCube\nCube\nTetrahedron\nDodecahedron\nDodecahedron\nDodecahedron\nIcosahedron\nIcosahedron\nDodecahedron\nIcosahedron\nDodecahedron\nDodecahedron\nIcosahedron\nIcosahedron",
"output": "340"
}
] | 1,693,329,691
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 31
| 0
|
n = int(input())
ans = 0
while(n):
shape = input()
if shape=="Tetrahedron":
ans += 6
elif shape=="Dodecahedron":
ans += 12
elif shape=="Icosahedron":
ans += 20
elif shape=="Octahedron":
ans += 8
else:
ans += 4
n = n -1
print(ans)
|
Title: Anton and Polyhedrons
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Anton's favourite geometric figures are regular polyhedrons. Note that there are five kinds of regular polyhedrons:
- Tetrahedron. Tetrahedron has 4 triangular faces. - Cube. Cube has 6 square faces. - Octahedron. Octahedron has 8 triangular faces. - Dodecahedron. Dodecahedron has 12 pentagonal faces. - Icosahedron. Icosahedron has 20 triangular faces.
All five kinds of polyhedrons are shown on the picture below:
Anton has a collection of *n* polyhedrons. One day he decided to know, how many faces his polyhedrons have in total. Help Anton and find this number!
Input Specification:
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=200<=000) — the number of polyhedrons in Anton's collection.
Each of the following *n* lines of the input contains a string *s**i* — the name of the *i*-th polyhedron in Anton's collection. The string can look like this:
- "Tetrahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is a tetrahedron. - "Cube" (without quotes), if the *i*-th polyhedron in Anton's collection is a cube. - "Octahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is an octahedron. - "Dodecahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is a dodecahedron. - "Icosahedron" (without quotes), if the *i*-th polyhedron in Anton's collection is an icosahedron.
Output Specification:
Output one number — the total number of faces in all the polyhedrons in Anton's collection.
Demo Input:
['4\nIcosahedron\nCube\nTetrahedron\nDodecahedron\n', '3\nDodecahedron\nOctahedron\nOctahedron\n']
Demo Output:
['42\n', '28\n']
Note:
In the first sample Anton has one icosahedron, one cube, one tetrahedron and one dodecahedron. Icosahedron has 20 faces, cube has 6 faces, tetrahedron has 4 faces and dodecahedron has 12 faces. In total, they have 20 + 6 + 4 + 12 = 42 faces.
|
```python
n = int(input())
ans = 0
while(n):
shape = input()
if shape=="Tetrahedron":
ans += 6
elif shape=="Dodecahedron":
ans += 12
elif shape=="Icosahedron":
ans += 20
elif shape=="Octahedron":
ans += 8
else:
ans += 4
n = n -1
print(ans)
```
| 0
|
|
350
|
C
|
Bombs
|
PROGRAMMING
| 1,600
|
[
"greedy",
"implementation",
"sortings"
] | null | null |
You've got a robot, its task is destroying bombs on a square plane. Specifically, the square plane contains *n* bombs, the *i*-th bomb is at point with coordinates (*x**i*,<=*y**i*). We know that no two bombs are at the same point and that no bomb is at point with coordinates (0,<=0). Initially, the robot is at point with coordinates (0,<=0). Also, let's mark the robot's current position as (*x*,<=*y*). In order to destroy all the bombs, the robot can perform three types of operations:
1. Operation has format "1 k dir". To perform the operation robot have to move in direction *dir* *k* (*k*<=≥<=1) times. There are only 4 directions the robot can move in: "R", "L", "U", "D". During one move the robot can move from the current point to one of following points: (*x*<=+<=1,<=*y*), (*x*<=-<=1,<=*y*), (*x*,<=*y*<=+<=1), (*x*,<=*y*<=-<=1) (corresponding to directions). It is forbidden to move from point (*x*,<=*y*), if at least one point on the path (besides the destination point) contains a bomb. 1. Operation has format "2". To perform the operation robot have to pick a bomb at point (*x*,<=*y*) and put it in a special container. Thus, the robot can carry the bomb from any point to any other point. The operation cannot be performed if point (*x*,<=*y*) has no bomb. It is forbidden to pick a bomb if the robot already has a bomb in its container. 1. Operation has format "3". To perform the operation robot have to take a bomb out of the container and destroy it. You are allowed to perform this operation only if the robot is at point (0,<=0). It is forbidden to perform the operation if the container has no bomb.
Help the robot and find the shortest possible sequence of operations he can perform to destroy all bombs on the coordinate plane.
|
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=105) — the number of bombs on the coordinate plane. Next *n* lines contain two integers each. The *i*-th line contains numbers (*x**i*,<=*y**i*) (<=-<=109<=≤<=*x**i*,<=*y**i*<=≤<=109) — the coordinates of the *i*-th bomb. It is guaranteed that no two bombs are located at the same point and no bomb is at point (0,<=0).
|
In a single line print a single integer *k* — the minimum number of operations needed to destroy all bombs. On the next lines print the descriptions of these *k* operations. If there are multiple sequences, you can print any of them. It is guaranteed that there is the solution where *k*<=≤<=106.
|
[
"2\n1 1\n-1 -1\n",
"3\n5 0\n0 5\n1 0\n"
] |
[
"12\n1 1 R\n1 1 U\n2\n1 1 L\n1 1 D\n3\n1 1 L\n1 1 D\n2\n1 1 R\n1 1 U\n3\n",
"12\n1 1 R\n2\n1 1 L\n3\n1 5 R\n2\n1 5 L\n3\n1 5 U\n2\n1 5 D\n3\n"
] |
none
| 1,000
|
[
{
"input": "2\n1 1\n-1 -1",
"output": "12\n1 1 R\n1 1 U\n2\n1 1 L\n1 1 D\n3\n1 1 L\n1 1 D\n2\n1 1 R\n1 1 U\n3"
},
{
"input": "3\n5 0\n0 5\n1 0",
"output": "12\n1 1 R\n2\n1 1 L\n3\n1 5 R\n2\n1 5 L\n3\n1 5 U\n2\n1 5 D\n3"
},
{
"input": "1\n-277226476 314722425",
"output": "6\n1 277226476 L\n1 314722425 U\n2\n1 277226476 R\n1 314722425 D\n3"
},
{
"input": "2\n-404192496 -968658337\n556071553 -256244640",
"output": "12\n1 556071553 R\n1 256244640 D\n2\n1 556071553 L\n1 256244640 U\n3\n1 404192496 L\n1 968658337 D\n2\n1 404192496 R\n1 968658337 U\n3"
},
{
"input": "24\n-2 -2\n-1 1\n0 1\n1 1\n0 2\n1 -1\n2 -2\n1 -2\n-1 0\n0 -2\n0 -1\n-2 0\n-2 -1\n2 -1\n2 2\n-1 -2\n-2 1\n2 0\n-1 2\n1 2\n-1 -1\n1 0\n2 1\n-2 2",
"output": "128\n1 1 U\n2\n1 1 D\n3\n1 1 R\n2\n1 1 L\n3\n1 1 L\n2\n1 1 R\n3\n1 1 D\n2\n1 1 U\n3\n1 1 L\n1 1 U\n2\n1 1 R\n1 1 D\n3\n1 1 R\n1 1 U\n2\n1 1 L\n1 1 D\n3\n1 2 U\n2\n1 2 D\n3\n1 1 R\n1 1 D\n2\n1 1 L\n1 1 U\n3\n1 2 D\n2\n1 2 U\n3\n1 2 L\n2\n1 2 R\n3\n1 1 L\n1 1 D\n2\n1 1 R\n1 1 U\n3\n1 2 R\n2\n1 2 L\n3\n1 2 L\n1 1 D\n2\n1 2 R\n1 1 U\n3\n1 2 R\n1 1 U\n2\n1 2 L\n1 1 D\n3\n1 1 R\n1 2 U\n2\n1 1 L\n1 2 D\n3\n1 1 L\n1 2 U\n2\n1 1 R\n1 2 D\n3\n1 2 L\n1 1 U\n2\n1 2 R\n1 1 D\n3\n1 1 L\n1 2 D\n2\n1 1 R\n1 2 U\n3\n1 2 R\n..."
}
] | 1,594,404,334
| 2,147,483,647
|
PyPy 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 4
| 2,000
| 91,136,000
|
import sys
input = sys.stdin.readline
I = lambda : list(map(int,input().split()))
n,=I()
l=[]
r=[];k=0
for i in range(n):
x,y=I()
if x<0:
l.append([x,y])
else:
r.append([x,y])
k = k+4 if x!=0 and y!=0 else k+2
k+=2*n;an=[]
l.sort(reverse=True);r.sort()
for x,y in r:
if x!=0:
an.append([1,x,'R'])
if y!=0:
an.append([1,abs(y),('U' if y>0 else 'D')])
an.append([2])
if x!=0:
an.append([1,x,'L'])
if y!=0:
an.append([1,abs(y),('D' if y>0 else 'U')])
an.append([3])
for x,y in l:
x=-x
if x!=0:
an.append([1,x,'L'])
if y!=0:
an.append([1,abs(y),('U' if y>0 else 'D')])
an.append([2])
if x!=0:
an.append([1,x,'R'])
if y!=0:
an.append([1,abs(y),('D' if y>0 else 'U')])
an.append([3])
print(k)
for i in an:
print(*i)
|
Title: Bombs
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You've got a robot, its task is destroying bombs on a square plane. Specifically, the square plane contains *n* bombs, the *i*-th bomb is at point with coordinates (*x**i*,<=*y**i*). We know that no two bombs are at the same point and that no bomb is at point with coordinates (0,<=0). Initially, the robot is at point with coordinates (0,<=0). Also, let's mark the robot's current position as (*x*,<=*y*). In order to destroy all the bombs, the robot can perform three types of operations:
1. Operation has format "1 k dir". To perform the operation robot have to move in direction *dir* *k* (*k*<=≥<=1) times. There are only 4 directions the robot can move in: "R", "L", "U", "D". During one move the robot can move from the current point to one of following points: (*x*<=+<=1,<=*y*), (*x*<=-<=1,<=*y*), (*x*,<=*y*<=+<=1), (*x*,<=*y*<=-<=1) (corresponding to directions). It is forbidden to move from point (*x*,<=*y*), if at least one point on the path (besides the destination point) contains a bomb. 1. Operation has format "2". To perform the operation robot have to pick a bomb at point (*x*,<=*y*) and put it in a special container. Thus, the robot can carry the bomb from any point to any other point. The operation cannot be performed if point (*x*,<=*y*) has no bomb. It is forbidden to pick a bomb if the robot already has a bomb in its container. 1. Operation has format "3". To perform the operation robot have to take a bomb out of the container and destroy it. You are allowed to perform this operation only if the robot is at point (0,<=0). It is forbidden to perform the operation if the container has no bomb.
Help the robot and find the shortest possible sequence of operations he can perform to destroy all bombs on the coordinate plane.
Input Specification:
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=105) — the number of bombs on the coordinate plane. Next *n* lines contain two integers each. The *i*-th line contains numbers (*x**i*,<=*y**i*) (<=-<=109<=≤<=*x**i*,<=*y**i*<=≤<=109) — the coordinates of the *i*-th bomb. It is guaranteed that no two bombs are located at the same point and no bomb is at point (0,<=0).
Output Specification:
In a single line print a single integer *k* — the minimum number of operations needed to destroy all bombs. On the next lines print the descriptions of these *k* operations. If there are multiple sequences, you can print any of them. It is guaranteed that there is the solution where *k*<=≤<=106.
Demo Input:
['2\n1 1\n-1 -1\n', '3\n5 0\n0 5\n1 0\n']
Demo Output:
['12\n1 1 R\n1 1 U\n2\n1 1 L\n1 1 D\n3\n1 1 L\n1 1 D\n2\n1 1 R\n1 1 U\n3\n', '12\n1 1 R\n2\n1 1 L\n3\n1 5 R\n2\n1 5 L\n3\n1 5 U\n2\n1 5 D\n3\n']
Note:
none
|
```python
import sys
input = sys.stdin.readline
I = lambda : list(map(int,input().split()))
n,=I()
l=[]
r=[];k=0
for i in range(n):
x,y=I()
if x<0:
l.append([x,y])
else:
r.append([x,y])
k = k+4 if x!=0 and y!=0 else k+2
k+=2*n;an=[]
l.sort(reverse=True);r.sort()
for x,y in r:
if x!=0:
an.append([1,x,'R'])
if y!=0:
an.append([1,abs(y),('U' if y>0 else 'D')])
an.append([2])
if x!=0:
an.append([1,x,'L'])
if y!=0:
an.append([1,abs(y),('D' if y>0 else 'U')])
an.append([3])
for x,y in l:
x=-x
if x!=0:
an.append([1,x,'L'])
if y!=0:
an.append([1,abs(y),('U' if y>0 else 'D')])
an.append([2])
if x!=0:
an.append([1,x,'R'])
if y!=0:
an.append([1,abs(y),('D' if y>0 else 'U')])
an.append([3])
print(k)
for i in an:
print(*i)
```
| 0
|
|
0
|
none
|
none
|
none
| 0
|
[
"none"
] | null | null |
Natasha is going to fly on a rocket to Mars and return to Earth. Also, on the way to Mars, she will land on $n - 2$ intermediate planets. Formally: we number all the planets from $1$ to $n$. $1$ is Earth, $n$ is Mars. Natasha will make exactly $n$ flights: $1 \to 2 \to \ldots n \to 1$.
Flight from $x$ to $y$ consists of two phases: take-off from planet $x$ and landing to planet $y$. This way, the overall itinerary of the trip will be: the $1$-st planet $\to$ take-off from the $1$-st planet $\to$ landing to the $2$-nd planet $\to$ $2$-nd planet $\to$ take-off from the $2$-nd planet $\to$ $\ldots$ $\to$ landing to the $n$-th planet $\to$ the $n$-th planet $\to$ take-off from the $n$-th planet $\to$ landing to the $1$-st planet $\to$ the $1$-st planet.
The mass of the rocket together with all the useful cargo (but without fuel) is $m$ tons. However, Natasha does not know how much fuel to load into the rocket. Unfortunately, fuel can only be loaded on Earth, so if the rocket runs out of fuel on some other planet, Natasha will not be able to return home. Fuel is needed to take-off from each planet and to land to each planet. It is known that $1$ ton of fuel can lift off $a_i$ tons of rocket from the $i$-th planet or to land $b_i$ tons of rocket onto the $i$-th planet.
For example, if the weight of rocket is $9$ tons, weight of fuel is $3$ tons and take-off coefficient is $8$ ($a_i = 8$), then $1.5$ tons of fuel will be burnt (since $1.5 \cdot 8 = 9 + 3$). The new weight of fuel after take-off will be $1.5$ tons.
Please note, that it is allowed to burn non-integral amount of fuel during take-off or landing, and the amount of initial fuel can be non-integral as well.
Help Natasha to calculate the minimum mass of fuel to load into the rocket. Note, that the rocket must spend fuel to carry both useful cargo and the fuel itself. However, it doesn't need to carry the fuel which has already been burnt. Assume, that the rocket takes off and lands instantly.
|
The first line contains a single integer $n$ ($2 \le n \le 1000$) — number of planets.
The second line contains the only integer $m$ ($1 \le m \le 1000$) — weight of the payload.
The third line contains $n$ integers $a_1, a_2, \ldots, a_n$ ($1 \le a_i \le 1000$), where $a_i$ is the number of tons, which can be lifted off by one ton of fuel.
The fourth line contains $n$ integers $b_1, b_2, \ldots, b_n$ ($1 \le b_i \le 1000$), where $b_i$ is the number of tons, which can be landed by one ton of fuel.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
|
If Natasha can fly to Mars through $(n - 2)$ planets and return to Earth, print the minimum mass of fuel (in tons) that Natasha should take. Otherwise, print a single number $-1$.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
The answer will be considered correct if its absolute or relative error doesn't exceed $10^{-6}$. Formally, let your answer be $p$, and the jury's answer be $q$. Your answer is considered correct if $\frac{|p - q|}{\max{(1, |q|)}} \le 10^{-6}$.
|
[
"2\n12\n11 8\n7 5\n",
"3\n1\n1 4 1\n2 5 3\n",
"6\n2\n4 6 3 3 5 6\n2 6 3 6 5 3\n"
] |
[
"10.0000000000\n",
"-1\n",
"85.4800000000\n"
] |
Let's consider the first example.
Initially, the mass of a rocket with fuel is $22$ tons.
- At take-off from Earth one ton of fuel can lift off $11$ tons of cargo, so to lift off $22$ tons you need to burn $2$ tons of fuel. Remaining weight of the rocket with fuel is $20$ tons.- During landing on Mars, one ton of fuel can land $5$ tons of cargo, so for landing $20$ tons you will need to burn $4$ tons of fuel. There will be $16$ tons of the rocket with fuel remaining.- While taking off from Mars, one ton of fuel can raise $8$ tons of cargo, so to lift off $16$ tons you will need to burn $2$ tons of fuel. There will be $14$ tons of rocket with fuel after that.- During landing on Earth, one ton of fuel can land $7$ tons of cargo, so for landing $14$ tons you will need to burn $2$ tons of fuel. Remaining weight is $12$ tons, that is, a rocket without any fuel.
In the second case, the rocket will not be able even to take off from Earth.
| 0
|
[
{
"input": "2\n12\n11 8\n7 5",
"output": "10.0000000000"
},
{
"input": "3\n1\n1 4 1\n2 5 3",
"output": "-1"
},
{
"input": "6\n2\n4 6 3 3 5 6\n2 6 3 6 5 3",
"output": "85.4800000000"
},
{
"input": "3\n3\n1 2 1\n2 2 2",
"output": "-1"
},
{
"input": "4\n4\n2 3 2 2\n2 3 4 3",
"output": "284.0000000000"
},
{
"input": "5\n2\n1 2 2 1 2\n4 5 1 4 1",
"output": "-1"
},
{
"input": "7\n7\n3 2 6 2 2 2 5\n4 7 5 6 2 2 2",
"output": "4697.0000000000"
},
{
"input": "2\n1000\n12 34\n56 78",
"output": "159.2650775220"
},
{
"input": "8\n4\n1 1 4 1 3 1 8 1\n1 1 1 1 1 3 1 2",
"output": "-1"
},
{
"input": "9\n2\n8 7 1 1 3 7 1 2 4\n4 1 1 8 7 7 1 1 5",
"output": "-1"
},
{
"input": "10\n10\n9 8 8 7 2 10 2 9 2 4\n3 10 6 2 6 6 5 9 4 5",
"output": "3075.7142857143"
},
{
"input": "20\n12\n3 9 12 13 16 18 9 9 19 7 2 5 17 14 7 7 15 16 5 7\n16 9 13 5 14 10 4 3 16 16 12 20 17 11 4 5 5 14 6 15",
"output": "4670.8944493007"
},
{
"input": "30\n5\n25 1 28 1 27 25 24 1 28 1 12 1 29 16 1 1 1 1 27 1 24 1 1 1 1 1 1 1 30 3\n1 22 1 1 24 2 13 1 16 21 1 27 14 16 1 1 7 1 1 18 1 23 10 1 15 16 16 15 10 1",
"output": "-1"
},
{
"input": "40\n13\n1 1 1 23 21 1 1 1 1 1 40 32 1 21 1 8 1 1 36 15 33 1 30 1 1 37 22 1 4 39 7 1 9 37 1 1 1 28 1 1\n1 34 17 1 38 20 8 14 1 18 29 3 21 21 18 14 1 11 1 1 23 1 25 1 14 1 7 31 9 20 25 1 1 1 1 8 26 12 1 1",
"output": "-1"
},
{
"input": "50\n19\n17 7 13 42 19 25 10 25 2 36 17 40 30 48 34 43 34 20 5 15 8 7 43 35 21 40 40 19 30 11 49 7 24 23 43 30 38 49 10 8 30 11 28 50 48 25 25 20 48 24\n49 35 10 22 24 50 50 7 6 13 16 35 12 43 50 44 35 33 38 49 26 18 23 37 7 38 23 20 28 48 41 16 6 32 32 34 11 39 38 9 38 23 16 31 37 47 33 20 46 30",
"output": "7832.1821424977"
},
{
"input": "60\n21\n11 35 1 28 39 13 19 56 13 13 21 25 1 1 23 1 52 26 53 1 1 1 30 39 1 7 1 1 3 1 1 10 1 1 37 1 1 25 1 1 1 53 1 3 48 1 6 5 4 15 1 14 25 53 25 38 27 1 1 1\n1 1 1 35 40 58 10 22 1 56 1 59 1 6 33 1 1 1 1 18 14 1 1 40 25 47 1 34 1 1 53 1 1 25 1 45 1 1 25 34 3 1 1 1 53 27 11 58 1 1 1 10 12 1 1 1 31 52 1 1",
"output": "-1"
},
{
"input": "70\n69\n70 66 57 58 24 60 39 2 48 61 65 22 10 26 68 62 48 25 12 14 45 57 6 30 48 15 46 33 42 28 69 42 64 25 24 8 62 12 68 53 55 20 32 70 3 5 41 49 16 26 2 34 34 20 39 65 18 47 62 31 39 28 61 67 7 14 31 31 53 54\n40 33 24 20 68 20 22 39 53 56 48 38 59 45 47 46 7 69 11 58 61 40 35 38 62 66 18 36 44 48 67 24 14 27 67 63 68 30 50 6 58 7 6 35 20 58 6 12 12 23 14 2 63 27 29 22 49 16 55 40 70 27 27 70 42 38 66 55 69 47",
"output": "217989.4794743629"
},
{
"input": "80\n21\n65 4 26 25 1 1 1 1 1 1 60 1 29 43 48 6 48 13 29 1 1 62 1 1 1 1 1 1 1 26 9 1 22 1 35 13 66 36 1 1 1 38 55 21 70 1 58 70 1 1 38 1 1 20 1 1 51 1 1 28 1 23 11 1 39 47 1 52 41 1 63 1 1 52 1 45 11 10 80 1\n1 1 25 30 1 1 55 54 1 48 10 37 22 1 74 1 78 13 1 65 32 1 1 1 1 69 5 59 1 1 65 1 40 1 31 1 1 75 54 1 60 1 1 1 1 1 1 1 11 29 36 1 72 71 52 1 1 1 37 1 1 75 43 9 53 1 62 1 29 1 40 27 59 74 41 53 19 30 1 73",
"output": "-1"
},
{
"input": "90\n35\n1 68 16 30 24 1 1 1 35 1 1 67 1 1 1 1 33 16 37 77 83 1 77 26 1 1 68 67 70 62 1 47 1 1 1 84 1 65 1 32 83 1 1 1 28 1 71 76 84 1 1 5 1 74 10 1 1 1 38 87 13 1 7 66 81 49 1 9 1 11 1 25 1 1 1 1 7 1 1 36 61 47 51 1 1 69 40 1 37 1\n40 1 21 1 19 51 37 52 64 1 86 1 5 24 1 1 1 19 36 1 1 77 24 4 1 18 89 1 1 1 1 1 29 22 1 80 32 36 6 1 63 1 30 1 1 1 86 79 73 52 9 1 1 11 7 1 25 20 1 20 1 49 1 37 1 41 1 1 1 1 54 55 1 10 1 1 1 1 1 1 66 1 68 1 1 1 1 53 1 1",
"output": "-1"
},
{
"input": "2\n1\n1 1\n1 1",
"output": "-1"
},
{
"input": "2\n1\n1 1\n2 2",
"output": "-1"
},
{
"input": "2\n1\n2 2\n1 1",
"output": "-1"
},
{
"input": "2\n1\n2 2\n2 2",
"output": "15.0000000000"
},
{
"input": "2\n2\n1 1\n1 1",
"output": "-1"
},
{
"input": "2\n2\n1 1\n2 2",
"output": "-1"
},
{
"input": "2\n2\n2 2\n1 1",
"output": "-1"
},
{
"input": "2\n2\n2 2\n2 2",
"output": "30.0000000000"
},
{
"input": "40\n55\n1 382 1 1 1 629 111 689 396 614 1 1 995 148 7 820 913 1 1 169 157 1 702 1 159 1 1 226 1 253 1 319 1 130 1 1 1 466 1 756\n1 23 555 1 412 1 1 373 316 234 888 1 112 818 33 443 313 1 235 1 1 610 110 535 1 445 1 386 1 1 758 1 292 1 862 1 244 428 530 1",
"output": "-1"
},
{
"input": "49\n1\n100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100\n3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3",
"output": "695580114.6380882263"
},
{
"input": "2\n12\n11 8\n1 1",
"output": "-1"
},
{
"input": "3\n3\n7 11 17\n19 31 33",
"output": "1.6012429470"
}
] | 1,536,867,207
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 76
| 187
| 0
|
from sys import stdin
n=int(stdin.readline())
m=int(stdin.readline())
a=[int(x) for x in stdin.readline().split()]
b=[int(x) for x in stdin.readline().split()]
w = m
for i in range(n):
ax = a[-i-1]
bx = b[-i]
if ax == 1 or bx == 1:
print(-1)
exit()
w += w/(bx-1.0)
w += w/(ax-1.0)
print(w-m)
|
Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Natasha is going to fly on a rocket to Mars and return to Earth. Also, on the way to Mars, she will land on $n - 2$ intermediate planets. Formally: we number all the planets from $1$ to $n$. $1$ is Earth, $n$ is Mars. Natasha will make exactly $n$ flights: $1 \to 2 \to \ldots n \to 1$.
Flight from $x$ to $y$ consists of two phases: take-off from planet $x$ and landing to planet $y$. This way, the overall itinerary of the trip will be: the $1$-st planet $\to$ take-off from the $1$-st planet $\to$ landing to the $2$-nd planet $\to$ $2$-nd planet $\to$ take-off from the $2$-nd planet $\to$ $\ldots$ $\to$ landing to the $n$-th planet $\to$ the $n$-th planet $\to$ take-off from the $n$-th planet $\to$ landing to the $1$-st planet $\to$ the $1$-st planet.
The mass of the rocket together with all the useful cargo (but without fuel) is $m$ tons. However, Natasha does not know how much fuel to load into the rocket. Unfortunately, fuel can only be loaded on Earth, so if the rocket runs out of fuel on some other planet, Natasha will not be able to return home. Fuel is needed to take-off from each planet and to land to each planet. It is known that $1$ ton of fuel can lift off $a_i$ tons of rocket from the $i$-th planet or to land $b_i$ tons of rocket onto the $i$-th planet.
For example, if the weight of rocket is $9$ tons, weight of fuel is $3$ tons and take-off coefficient is $8$ ($a_i = 8$), then $1.5$ tons of fuel will be burnt (since $1.5 \cdot 8 = 9 + 3$). The new weight of fuel after take-off will be $1.5$ tons.
Please note, that it is allowed to burn non-integral amount of fuel during take-off or landing, and the amount of initial fuel can be non-integral as well.
Help Natasha to calculate the minimum mass of fuel to load into the rocket. Note, that the rocket must spend fuel to carry both useful cargo and the fuel itself. However, it doesn't need to carry the fuel which has already been burnt. Assume, that the rocket takes off and lands instantly.
Input Specification:
The first line contains a single integer $n$ ($2 \le n \le 1000$) — number of planets.
The second line contains the only integer $m$ ($1 \le m \le 1000$) — weight of the payload.
The third line contains $n$ integers $a_1, a_2, \ldots, a_n$ ($1 \le a_i \le 1000$), where $a_i$ is the number of tons, which can be lifted off by one ton of fuel.
The fourth line contains $n$ integers $b_1, b_2, \ldots, b_n$ ($1 \le b_i \le 1000$), where $b_i$ is the number of tons, which can be landed by one ton of fuel.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
Output Specification:
If Natasha can fly to Mars through $(n - 2)$ planets and return to Earth, print the minimum mass of fuel (in tons) that Natasha should take. Otherwise, print a single number $-1$.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
The answer will be considered correct if its absolute or relative error doesn't exceed $10^{-6}$. Formally, let your answer be $p$, and the jury's answer be $q$. Your answer is considered correct if $\frac{|p - q|}{\max{(1, |q|)}} \le 10^{-6}$.
Demo Input:
['2\n12\n11 8\n7 5\n', '3\n1\n1 4 1\n2 5 3\n', '6\n2\n4 6 3 3 5 6\n2 6 3 6 5 3\n']
Demo Output:
['10.0000000000\n', '-1\n', '85.4800000000\n']
Note:
Let's consider the first example.
Initially, the mass of a rocket with fuel is $22$ tons.
- At take-off from Earth one ton of fuel can lift off $11$ tons of cargo, so to lift off $22$ tons you need to burn $2$ tons of fuel. Remaining weight of the rocket with fuel is $20$ tons.- During landing on Mars, one ton of fuel can land $5$ tons of cargo, so for landing $20$ tons you will need to burn $4$ tons of fuel. There will be $16$ tons of the rocket with fuel remaining.- While taking off from Mars, one ton of fuel can raise $8$ tons of cargo, so to lift off $16$ tons you will need to burn $2$ tons of fuel. There will be $14$ tons of rocket with fuel after that.- During landing on Earth, one ton of fuel can land $7$ tons of cargo, so for landing $14$ tons you will need to burn $2$ tons of fuel. Remaining weight is $12$ tons, that is, a rocket without any fuel.
In the second case, the rocket will not be able even to take off from Earth.
|
```python
from sys import stdin
n=int(stdin.readline())
m=int(stdin.readline())
a=[int(x) for x in stdin.readline().split()]
b=[int(x) for x in stdin.readline().split()]
w = m
for i in range(n):
ax = a[-i-1]
bx = b[-i]
if ax == 1 or bx == 1:
print(-1)
exit()
w += w/(bx-1.0)
w += w/(ax-1.0)
print(w-m)
```
| 3
|
|
540
|
A
|
Combination Lock
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Scrooge McDuck keeps his most treasured savings in a home safe with a combination lock. Each time he wants to put there the treasures that he's earned fair and square, he has to open the lock.
The combination lock is represented by *n* rotating disks with digits from 0 to 9 written on them. Scrooge McDuck has to turn some disks so that the combination of digits on the disks forms a secret combination. In one move, he can rotate one disk one digit forwards or backwards. In particular, in one move he can go from digit 0 to digit 9 and vice versa. What minimum number of actions does he need for that?
|
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of disks on the combination lock.
The second line contains a string of *n* digits — the original state of the disks.
The third line contains a string of *n* digits — Scrooge McDuck's combination that opens the lock.
|
Print a single integer — the minimum number of moves Scrooge McDuck needs to open the lock.
|
[
"5\n82195\n64723\n"
] |
[
"13\n"
] |
In the sample he needs 13 moves:
- 1 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b8967f65a723782358b93eff9ce69f336817cf70.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 2 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/07fa58573ece0d32c4d555e498d2b24d2f70f36a.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 3 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/cc2275d9252aae35a6867c6a5b4ba7596e9a7626.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 4 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b100aea470fcaaab4e9529b234ba0d7875943c10.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 5 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/eb2cbe4324cebca65b85816262a85e473cd65967.png" style="max-width: 100.0%;max-height: 100.0%;"/>
| 500
|
[
{
"input": "5\n82195\n64723",
"output": "13"
},
{
"input": "12\n102021090898\n010212908089",
"output": "16"
},
{
"input": "1\n8\n1",
"output": "3"
},
{
"input": "2\n83\n57",
"output": "7"
},
{
"input": "10\n0728592530\n1362615763",
"output": "27"
},
{
"input": "100\n4176196363694273682807653052945037727131821799902563705176501742060696655282954944720643131654235909\n3459912084922154505910287499879975659298239371519889866585472674423008837878123067103005344986554746",
"output": "245"
},
{
"input": "1\n8\n1",
"output": "3"
},
{
"input": "2\n83\n57",
"output": "7"
},
{
"input": "3\n607\n684",
"output": "5"
},
{
"input": "4\n0809\n0636",
"output": "8"
},
{
"input": "5\n84284\n08941",
"output": "16"
},
{
"input": "25\n8037856825987124762280548\n9519431339078678836940020",
"output": "72"
},
{
"input": "125\n23269567683904664184142384849516523616863461607751021071772615078579713054027902974007001544768640273491193035874486891541257\n47635110303703399505805044019026243695451609639556649012447370081552870340011971572363458960190590266459684717415349529509024",
"output": "305"
},
{
"input": "5\n84284\n08941",
"output": "16"
},
{
"input": "25\n8037856825987124762285484\n9519431339078678836940202",
"output": "74"
},
{
"input": "125\n23269567689466418414238845152168634610771021717726157879713054270294007001544768647391193035874486891412573389247025830678706\n47635110307339950580504010224954516093956649124473708152870340117152363458960190596659684717415349529090241694059599629136831",
"output": "357"
},
{
"input": "5\n84284\n08941",
"output": "16"
},
{
"input": "25\n8378525987476228048406972\n9194339078883694020217816",
"output": "55"
},
{
"input": "125\n23269576839046618414238484916523616863461607750210717761078579713054027902974007015447686027349193035874486891541257338624472\n47635103037033950580504401926243695451609639556490124437081552870340011971572363489601905026645984717415349529509024169604599",
"output": "274"
},
{
"input": "1\n0\n0",
"output": "0"
},
{
"input": "1\n7\n7",
"output": "0"
},
{
"input": "1\n0\n5",
"output": "5"
},
{
"input": "1\n2\n7",
"output": "5"
},
{
"input": "1\n7\n9",
"output": "2"
},
{
"input": "1\n9\n7",
"output": "2"
},
{
"input": "1\n2\n9",
"output": "3"
},
{
"input": "1\n9\n2",
"output": "3"
},
{
"input": "25\n3164978461316464614169874\n9413979197249127496597357",
"output": "66"
},
{
"input": "4\n9999\n9999",
"output": "0"
},
{
"input": "2\n11\n11",
"output": "0"
}
] | 1,664,094,986
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 43
| 62
| 0
|
n=int(input())
l=["0","1","2","3","4","5","6","7","8","9"]
s1=input()
s2=input()
res=0
for i in range(len(s1)):
c1=abs(int(s1[i])-int(s2[i]))
c2=10-abs(int(s1[i])-int(s2[i]))
# print(c1,c2)
res+=min(c1,c2)
print(res)
|
Title: Combination Lock
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Scrooge McDuck keeps his most treasured savings in a home safe with a combination lock. Each time he wants to put there the treasures that he's earned fair and square, he has to open the lock.
The combination lock is represented by *n* rotating disks with digits from 0 to 9 written on them. Scrooge McDuck has to turn some disks so that the combination of digits on the disks forms a secret combination. In one move, he can rotate one disk one digit forwards or backwards. In particular, in one move he can go from digit 0 to digit 9 and vice versa. What minimum number of actions does he need for that?
Input Specification:
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of disks on the combination lock.
The second line contains a string of *n* digits — the original state of the disks.
The third line contains a string of *n* digits — Scrooge McDuck's combination that opens the lock.
Output Specification:
Print a single integer — the minimum number of moves Scrooge McDuck needs to open the lock.
Demo Input:
['5\n82195\n64723\n']
Demo Output:
['13\n']
Note:
In the sample he needs 13 moves:
- 1 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b8967f65a723782358b93eff9ce69f336817cf70.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 2 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/07fa58573ece0d32c4d555e498d2b24d2f70f36a.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 3 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/cc2275d9252aae35a6867c6a5b4ba7596e9a7626.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 4 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/b100aea470fcaaab4e9529b234ba0d7875943c10.png" style="max-width: 100.0%;max-height: 100.0%;"/> - 5 disk: <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/eb2cbe4324cebca65b85816262a85e473cd65967.png" style="max-width: 100.0%;max-height: 100.0%;"/>
|
```python
n=int(input())
l=["0","1","2","3","4","5","6","7","8","9"]
s1=input()
s2=input()
res=0
for i in range(len(s1)):
c1=abs(int(s1[i])-int(s2[i]))
c2=10-abs(int(s1[i])-int(s2[i]))
# print(c1,c2)
res+=min(c1,c2)
print(res)
```
| 3
|
|
898
|
C
|
Phone Numbers
|
PROGRAMMING
| 1,400
|
[
"implementation",
"strings"
] | null | null |
Vasya has several phone books, in which he recorded the telephone numbers of his friends. Each of his friends can have one or several phone numbers.
Vasya decided to organize information about the phone numbers of friends. You will be given *n* strings — all entries from Vasya's phone books. Each entry starts with a friend's name. Then follows the number of phone numbers in the current entry, and then the phone numbers themselves. It is possible that several identical phones are recorded in the same record.
Vasya also believes that if the phone number *a* is a suffix of the phone number *b* (that is, the number *b* ends up with *a*), and both numbers are written by Vasya as the phone numbers of the same person, then *a* is recorded without the city code and it should not be taken into account.
The task is to print organized information about the phone numbers of Vasya's friends. It is possible that two different people have the same number. If one person has two numbers *x* and *y*, and *x* is a suffix of *y* (that is, *y* ends in *x*), then you shouldn't print number *x*. If the number of a friend in the Vasya's phone books is recorded several times in the same format, it is necessary to take it into account exactly once.
Read the examples to understand statement and format of the output better.
|
First line contains the integer *n* (1<=≤<=*n*<=≤<=20) — number of entries in Vasya's phone books.
The following *n* lines are followed by descriptions of the records in the format described in statement. Names of Vasya's friends are non-empty strings whose length does not exceed 10. They consists only of lowercase English letters. Number of phone numbers in one entry is not less than 1 is not more than 10. The telephone numbers consist of digits only. If you represent a phone number as a string, then its length will be in range from 1 to 10. Phone numbers can contain leading zeros.
|
Print out the ordered information about the phone numbers of Vasya's friends. First output *m* — number of friends that are found in Vasya's phone books.
The following *m* lines must contain entries in the following format "name number_of_phone_numbers phone_numbers". Phone numbers should be separated by a space. Each record must contain all the phone numbers of current friend.
Entries can be displayed in arbitrary order, phone numbers for one record can also be printed in arbitrary order.
|
[
"2\nivan 1 00123\nmasha 1 00123\n",
"3\nkarl 2 612 12\npetr 1 12\nkatya 1 612\n",
"4\nivan 3 123 123 456\nivan 2 456 456\nivan 8 789 3 23 6 56 9 89 2\ndasha 2 23 789\n"
] |
[
"2\nmasha 1 00123 \nivan 1 00123 \n",
"3\nkatya 1 612 \npetr 1 12 \nkarl 1 612 \n",
"2\ndasha 2 23 789 \nivan 4 789 123 2 456 \n"
] |
none
| 1,500
|
[
{
"input": "2\nivan 1 00123\nmasha 1 00123",
"output": "2\nmasha 1 00123 \nivan 1 00123 "
},
{
"input": "3\nkarl 2 612 12\npetr 1 12\nkatya 1 612",
"output": "3\nkatya 1 612 \npetr 1 12 \nkarl 1 612 "
},
{
"input": "4\nivan 3 123 123 456\nivan 2 456 456\nivan 8 789 3 23 6 56 9 89 2\ndasha 2 23 789",
"output": "2\ndasha 2 789 23 \nivan 4 2 123 456 789 "
},
{
"input": "20\nnxj 6 7 6 6 7 7 7\nnxj 10 8 5 1 7 6 1 0 7 0 6\nnxj 2 6 5\nnxj 10 6 7 6 6 5 8 3 6 6 8\nnxj 10 6 1 7 6 7 1 8 7 8 6\nnxj 10 8 5 8 6 5 6 1 9 6 3\nnxj 10 8 1 6 4 8 0 4 6 0 1\nnxj 9 2 6 6 8 1 1 3 6 6\nnxj 10 8 9 0 9 1 3 2 3 2 3\nnxj 6 6 7 0 8 1 2\nnxj 7 7 7 8 1 3 6 9\nnxj 10 2 7 0 1 5 1 9 1 2 6\nnxj 6 9 6 9 6 3 7\nnxj 9 0 1 7 8 2 6 6 5 6\nnxj 4 0 2 3 7\nnxj 10 0 4 0 6 1 1 8 8 4 7\nnxj 8 4 6 2 6 6 1 2 7\nnxj 10 5 3 4 2 1 0 7 0 7 6\nnxj 10 9 6 0 6 1 6 2 1 9 6\nnxj 4 2 9 0 1",
"output": "1\nnxj 10 4 1 8 7 5 3 6 9 0 2 "
},
{
"input": "20\nl 6 02 02 2 02 02 2\nl 8 8 8 8 2 62 13 31 3\ne 9 0 91 0 0 60 91 60 2 44\ne 9 69 2 1 44 2 91 66 1 70\nl 9 7 27 27 3 1 3 7 80 81\nl 9 2 1 13 7 2 10 02 3 92\ne 9 0 15 3 5 5 15 91 09 44\nl 7 2 50 4 5 98 31 98\nl 3 26 7 3\ne 6 7 5 0 62 65 91\nl 8 80 0 4 0 2 2 0 13\nl 9 19 13 02 2 1 4 19 26 02\nl 10 7 39 7 9 22 22 26 2 90 4\ne 7 65 2 36 0 34 57 9\ne 8 13 02 09 91 73 5 36 62\nl 9 75 0 10 8 76 7 82 8 34\nl 7 34 0 19 80 6 4 7\ne 5 4 2 5 7 2\ne 7 4 02 69 7 07 20 2\nl 4 8 2 1 63",
"output": "2\ne 18 70 07 62 36 20 69 66 57 02 65 34 44 73 60 91 15 09 13 \nl 21 02 80 27 63 19 50 81 76 34 90 98 92 31 26 22 75 39 13 10 82 62 "
},
{
"input": "20\no 10 6 6 97 45 6 6 6 6 5 6\nl 8 5 5 5 19 59 5 8 5\nj 9 2 30 58 2 2 1 0 30 4\nc 10 1 1 7 51 7 7 51 1 1 1\no 9 7 97 87 70 2 19 2 14 6\ne 6 26 6 6 6 26 5\ng 9 3 3 3 3 3 78 69 8 9\nl 8 8 01 1 5 8 41 72 3\nz 10 1 2 2 2 9 1 9 1 6 7\ng 8 7 78 05 36 7 3 67 9\no 5 6 9 9 7 7\ne 10 30 2 1 1 2 5 04 0 6 6\ne 9 30 30 2 2 0 26 30 79 8\nt 10 2 2 9 29 7 7 7 9 2 9\nc 7 7 51 1 31 2 7 4\nc 9 83 1 6 78 94 74 54 8 32\ng 8 4 1 01 9 39 28 6 6\nt 7 9 2 01 4 4 9 58\nj 5 0 1 58 02 4\nw 10 80 0 91 91 06 91 9 9 27 7",
"output": "9\nw 5 91 06 27 9 80 \nt 6 01 29 4 58 2 7 \ne 8 2 8 30 04 26 5 79 1 \nl 8 8 41 72 01 19 59 3 5 \nj 5 58 02 1 4 30 \nz 5 7 9 6 2 1 \ng 10 39 67 3 01 36 4 05 69 78 28 \no 8 19 2 45 6 87 14 97 70 \nc 10 7 94 32 6 78 74 31 83 51 54 "
},
{
"input": "1\negew 5 3 123 23 1234 134",
"output": "1\negew 3 134 123 1234 "
}
] | 1,698,594,941
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 0
| 77
| 3,584,000
|
import collections
import queue
from sys import stdin, stdout
input_int = lambda: int(stdin.readline())
input_1D_int = lambda: [int(x) for x in stdin.readline().split()]
input_2D_int = lambda n: [input_1D_int() for _ in range(n)]
input_string = lambda: stdin.readline().strip()
input_1D_string = lambda: [str(x) for x in stdin.readline().split()]
input_2D_string = lambda n: [input_1D_string() for _ in range(n)]
pr = lambda args, sep: stdout.write(sep.join(map(str, args)) + '\n')
chars, oo = 'abcdefghijklmnopqrstuvwxyz', int(1e18)
n = input_int()
map = collections.defaultdict(set)
for _ in range(n):
input = input_1D_string()
a = set(input[2:])
for j in a:
map[input[0]].add(j)
answer = []
for i in map:
answer = []
for j in map[i]:
for k in map[i]:
if len(j) < len(k) and j == k[-len(j):]:
break
else:
answer.append(j)
print (i, len(answer)," ".join(answer))
|
Title: Phone Numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya has several phone books, in which he recorded the telephone numbers of his friends. Each of his friends can have one or several phone numbers.
Vasya decided to organize information about the phone numbers of friends. You will be given *n* strings — all entries from Vasya's phone books. Each entry starts with a friend's name. Then follows the number of phone numbers in the current entry, and then the phone numbers themselves. It is possible that several identical phones are recorded in the same record.
Vasya also believes that if the phone number *a* is a suffix of the phone number *b* (that is, the number *b* ends up with *a*), and both numbers are written by Vasya as the phone numbers of the same person, then *a* is recorded without the city code and it should not be taken into account.
The task is to print organized information about the phone numbers of Vasya's friends. It is possible that two different people have the same number. If one person has two numbers *x* and *y*, and *x* is a suffix of *y* (that is, *y* ends in *x*), then you shouldn't print number *x*. If the number of a friend in the Vasya's phone books is recorded several times in the same format, it is necessary to take it into account exactly once.
Read the examples to understand statement and format of the output better.
Input Specification:
First line contains the integer *n* (1<=≤<=*n*<=≤<=20) — number of entries in Vasya's phone books.
The following *n* lines are followed by descriptions of the records in the format described in statement. Names of Vasya's friends are non-empty strings whose length does not exceed 10. They consists only of lowercase English letters. Number of phone numbers in one entry is not less than 1 is not more than 10. The telephone numbers consist of digits only. If you represent a phone number as a string, then its length will be in range from 1 to 10. Phone numbers can contain leading zeros.
Output Specification:
Print out the ordered information about the phone numbers of Vasya's friends. First output *m* — number of friends that are found in Vasya's phone books.
The following *m* lines must contain entries in the following format "name number_of_phone_numbers phone_numbers". Phone numbers should be separated by a space. Each record must contain all the phone numbers of current friend.
Entries can be displayed in arbitrary order, phone numbers for one record can also be printed in arbitrary order.
Demo Input:
['2\nivan 1 00123\nmasha 1 00123\n', '3\nkarl 2 612 12\npetr 1 12\nkatya 1 612\n', '4\nivan 3 123 123 456\nivan 2 456 456\nivan 8 789 3 23 6 56 9 89 2\ndasha 2 23 789\n']
Demo Output:
['2\nmasha 1 00123 \nivan 1 00123 \n', '3\nkatya 1 612 \npetr 1 12 \nkarl 1 612 \n', '2\ndasha 2 23 789 \nivan 4 789 123 2 456 \n']
Note:
none
|
```python
import collections
import queue
from sys import stdin, stdout
input_int = lambda: int(stdin.readline())
input_1D_int = lambda: [int(x) for x in stdin.readline().split()]
input_2D_int = lambda n: [input_1D_int() for _ in range(n)]
input_string = lambda: stdin.readline().strip()
input_1D_string = lambda: [str(x) for x in stdin.readline().split()]
input_2D_string = lambda n: [input_1D_string() for _ in range(n)]
pr = lambda args, sep: stdout.write(sep.join(map(str, args)) + '\n')
chars, oo = 'abcdefghijklmnopqrstuvwxyz', int(1e18)
n = input_int()
map = collections.defaultdict(set)
for _ in range(n):
input = input_1D_string()
a = set(input[2:])
for j in a:
map[input[0]].add(j)
answer = []
for i in map:
answer = []
for j in map[i]:
for k in map[i]:
if len(j) < len(k) and j == k[-len(j):]:
break
else:
answer.append(j)
print (i, len(answer)," ".join(answer))
```
| 0
|
|
982
|
A
|
Row
|
PROGRAMMING
| 1,200
|
[
"brute force",
"constructive algorithms"
] | null | null |
You're given a row with $n$ chairs. We call a seating of people "maximal" if the two following conditions hold:
1. There are no neighbors adjacent to anyone seated. 1. It's impossible to seat one more person without violating the first rule.
The seating is given as a string consisting of zeros and ones ($0$ means that the corresponding seat is empty, $1$ — occupied). The goal is to determine whether this seating is "maximal".
Note that the first and last seats are not adjacent (if $n \ne 2$).
|
The first line contains a single integer $n$ ($1 \leq n \leq 1000$) — the number of chairs.
The next line contains a string of $n$ characters, each of them is either zero or one, describing the seating.
|
Output "Yes" (without quotation marks) if the seating is "maximal". Otherwise print "No".
You are allowed to print letters in whatever case you'd like (uppercase or lowercase).
|
[
"3\n101\n",
"4\n1011\n",
"5\n10001\n"
] |
[
"Yes\n",
"No\n",
"No\n"
] |
In sample case one the given seating is maximal.
In sample case two the person at chair three has a neighbour to the right.
In sample case three it is possible to seat yet another person into chair three.
| 500
|
[
{
"input": "3\n101",
"output": "Yes"
},
{
"input": "4\n1011",
"output": "No"
},
{
"input": "5\n10001",
"output": "No"
},
{
"input": "1\n0",
"output": "No"
},
{
"input": "1\n1",
"output": "Yes"
},
{
"input": "100\n0101001010101001010010010101001010100101001001001010010101010010101001001010101001001001010100101010",
"output": "Yes"
},
{
"input": "4\n0100",
"output": "No"
},
{
"input": "42\n011000100101001001101011011010100010011010",
"output": "No"
},
{
"input": "3\n001",
"output": "No"
},
{
"input": "64\n1001001010010010100101010010010100100101001001001001010100101001",
"output": "Yes"
},
{
"input": "3\n111",
"output": "No"
},
{
"input": "4\n0000",
"output": "No"
},
{
"input": "4\n0001",
"output": "No"
},
{
"input": "4\n0010",
"output": "No"
},
{
"input": "4\n0011",
"output": "No"
},
{
"input": "4\n0101",
"output": "Yes"
},
{
"input": "4\n0110",
"output": "No"
},
{
"input": "4\n0111",
"output": "No"
},
{
"input": "4\n1000",
"output": "No"
},
{
"input": "4\n1001",
"output": "Yes"
},
{
"input": "4\n1010",
"output": "Yes"
},
{
"input": "4\n1100",
"output": "No"
},
{
"input": "4\n1101",
"output": "No"
},
{
"input": "4\n1110",
"output": "No"
},
{
"input": "4\n1111",
"output": "No"
},
{
"input": "2\n00",
"output": "No"
},
{
"input": "2\n01",
"output": "Yes"
},
{
"input": "2\n10",
"output": "Yes"
},
{
"input": "2\n11",
"output": "No"
},
{
"input": "3\n000",
"output": "No"
},
{
"input": "3\n010",
"output": "Yes"
},
{
"input": "3\n011",
"output": "No"
},
{
"input": "3\n100",
"output": "No"
},
{
"input": "3\n110",
"output": "No"
},
{
"input": "100\n0111001010101110001100000010011000100101110010001100111110101110001110101010111000010010011000000110",
"output": "No"
},
{
"input": "357\n100101010010010010010100101001001010101010100100100100101001010101001010010100101001010100101001010010100100101001010101010101001001010100101010010100101001010100100100101010010010010100101010010010101001010010010101001001010010010101010100100101010010100100101001010100101001010100101001010010010010100101001010100100100100100100100101010101010010010100101",
"output": "Yes"
},
{
"input": "459\n000111000101010000100001001010111110011011010001100101111010111011101110111101111101100101100011011001100110001001111001101000111001011100110100011111011111000010000110010011100110011011111110011100001101001111000100111011001000001011111100110100001001001100101011100001110110100101011011110100100111101011000101110000100110100100010000000100001001111111000011101010010011001111010111001100000100111001010111011010000011000011100101101011101000011011000110011",
"output": "No"
},
{
"input": "3\n001",
"output": "No"
},
{
"input": "4\n0010",
"output": "No"
},
{
"input": "3\n111",
"output": "No"
},
{
"input": "4\n0110",
"output": "No"
},
{
"input": "2\n11",
"output": "No"
},
{
"input": "2\n10",
"output": "Yes"
},
{
"input": "2\n01",
"output": "Yes"
},
{
"input": "4\n1101",
"output": "No"
},
{
"input": "2\n00",
"output": "No"
},
{
"input": "4\n1111",
"output": "No"
},
{
"input": "15\n000010101010000",
"output": "No"
},
{
"input": "8\n10010100",
"output": "No"
},
{
"input": "5\n00100",
"output": "No"
},
{
"input": "6\n100100",
"output": "No"
},
{
"input": "7\n1000001",
"output": "No"
},
{
"input": "98\n10101010101010101010101010101010101010101010101010101010101010101010101010101010101010101010101010",
"output": "Yes"
}
] | 1,658,084,999
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 55
| 93
| 0
|
input()
a = '0'+input()+'0'
print("No" if "000" in a or "11" in a else "Yes")
|
Title: Row
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You're given a row with $n$ chairs. We call a seating of people "maximal" if the two following conditions hold:
1. There are no neighbors adjacent to anyone seated. 1. It's impossible to seat one more person without violating the first rule.
The seating is given as a string consisting of zeros and ones ($0$ means that the corresponding seat is empty, $1$ — occupied). The goal is to determine whether this seating is "maximal".
Note that the first and last seats are not adjacent (if $n \ne 2$).
Input Specification:
The first line contains a single integer $n$ ($1 \leq n \leq 1000$) — the number of chairs.
The next line contains a string of $n$ characters, each of them is either zero or one, describing the seating.
Output Specification:
Output "Yes" (without quotation marks) if the seating is "maximal". Otherwise print "No".
You are allowed to print letters in whatever case you'd like (uppercase or lowercase).
Demo Input:
['3\n101\n', '4\n1011\n', '5\n10001\n']
Demo Output:
['Yes\n', 'No\n', 'No\n']
Note:
In sample case one the given seating is maximal.
In sample case two the person at chair three has a neighbour to the right.
In sample case three it is possible to seat yet another person into chair three.
|
```python
input()
a = '0'+input()+'0'
print("No" if "000" in a or "11" in a else "Yes")
```
| 3
|
|
139
|
A
|
Petr and Book
|
PROGRAMMING
| 1,000
|
[
"implementation"
] | null | null |
One Sunday Petr went to a bookshop and bought a new book on sports programming. The book had exactly *n* pages.
Petr decided to start reading it starting from the next day, that is, from Monday. Petr's got a very tight schedule and for each day of the week he knows how many pages he will be able to read on that day. Some days are so busy that Petr will have no time to read whatsoever. However, we know that he will be able to read at least one page a week.
Assuming that Petr will not skip days and will read as much as he can every day, determine on which day of the week he will read the last page of the book.
|
The first input line contains the single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of pages in the book.
The second line contains seven non-negative space-separated integers that do not exceed 1000 — those integers represent how many pages Petr can read on Monday, Tuesday, Wednesday, Thursday, Friday, Saturday and Sunday correspondingly. It is guaranteed that at least one of those numbers is larger than zero.
|
Print a single number — the number of the day of the week, when Petr will finish reading the book. The days of the week are numbered starting with one in the natural order: Monday, Tuesday, Wednesday, Thursday, Friday, Saturday, Sunday.
|
[
"100\n15 20 20 15 10 30 45\n",
"2\n1 0 0 0 0 0 0\n"
] |
[
"6\n",
"1\n"
] |
Note to the first sample:
By the end of Monday and therefore, by the beginning of Tuesday Petr has 85 pages left. He has 65 pages left by Wednesday, 45 by Thursday, 30 by Friday, 20 by Saturday and on Saturday Petr finishes reading the book (and he also has time to read 10 pages of something else).
Note to the second sample:
On Monday of the first week Petr will read the first page. On Monday of the second week Petr will read the second page and will finish reading the book.
| 500
|
[
{
"input": "100\n15 20 20 15 10 30 45",
"output": "6"
},
{
"input": "2\n1 0 0 0 0 0 0",
"output": "1"
},
{
"input": "100\n100 200 100 200 300 400 500",
"output": "1"
},
{
"input": "3\n1 1 1 1 1 1 1",
"output": "3"
},
{
"input": "1\n1 1 1 1 1 1 1",
"output": "1"
},
{
"input": "20\n5 3 7 2 1 6 4",
"output": "6"
},
{
"input": "10\n5 1 1 1 1 1 5",
"output": "6"
},
{
"input": "50\n10 1 10 1 10 1 10",
"output": "1"
},
{
"input": "77\n11 11 11 11 11 11 10",
"output": "1"
},
{
"input": "1\n1000 1000 1000 1000 1000 1000 1000",
"output": "1"
},
{
"input": "1000\n100 100 100 100 100 100 100",
"output": "3"
},
{
"input": "999\n10 20 10 20 30 20 10",
"output": "3"
},
{
"input": "433\n109 58 77 10 39 125 15",
"output": "7"
},
{
"input": "1\n0 0 0 0 0 0 1",
"output": "7"
},
{
"input": "5\n1 0 1 0 1 0 1",
"output": "1"
},
{
"input": "997\n1 1 0 0 1 0 1",
"output": "1"
},
{
"input": "1000\n1 1 1 1 1 1 1",
"output": "6"
},
{
"input": "1000\n1000 1000 1000 1000 1000 1000 1000",
"output": "1"
},
{
"input": "1000\n1 0 0 0 0 0 0",
"output": "1"
},
{
"input": "1000\n0 0 0 0 0 0 1",
"output": "7"
},
{
"input": "1000\n1 0 0 1 0 0 1",
"output": "1"
},
{
"input": "509\n105 23 98 0 7 0 155",
"output": "2"
},
{
"input": "7\n1 1 1 1 1 1 1",
"output": "7"
},
{
"input": "2\n1 1 0 0 0 0 0",
"output": "2"
},
{
"input": "1\n0 0 0 0 0 1 0",
"output": "6"
},
{
"input": "10\n0 0 0 0 0 0 1",
"output": "7"
},
{
"input": "5\n0 0 0 0 0 6 0",
"output": "6"
},
{
"input": "3\n0 1 0 0 0 0 0",
"output": "2"
},
{
"input": "10\n0 0 0 0 0 0 10",
"output": "7"
},
{
"input": "28\n1 2 3 4 5 6 7",
"output": "7"
},
{
"input": "100\n5 5 5 5 5 5 5",
"output": "6"
},
{
"input": "4\n1 0 0 0 0 0 1",
"output": "7"
},
{
"input": "2\n0 0 0 0 0 0 1",
"output": "7"
},
{
"input": "7\n0 0 0 0 0 0 7",
"output": "7"
},
{
"input": "7\n2 1 1 1 1 1 0",
"output": "6"
},
{
"input": "2\n0 0 1 1 0 0 0",
"output": "4"
},
{
"input": "6\n1 1 1 1 1 1 0",
"output": "6"
},
{
"input": "5\n1 1 1 0 0 1 1",
"output": "7"
},
{
"input": "100\n10 20 30 10 10 10 10",
"output": "7"
},
{
"input": "1\n0 0 0 1 0 0 0",
"output": "4"
},
{
"input": "70\n10 10 10 10 10 10 10",
"output": "7"
},
{
"input": "22\n1 2 3 4 5 6 10",
"output": "7"
},
{
"input": "5\n0 0 0 1 0 0 0",
"output": "4"
},
{
"input": "2\n0 0 0 1 0 0 0",
"output": "4"
},
{
"input": "6\n1 0 0 0 0 0 2",
"output": "7"
},
{
"input": "10\n1 2 2 1 2 1 1",
"output": "7"
},
{
"input": "5\n0 0 0 0 0 0 10",
"output": "7"
},
{
"input": "4\n0 1 1 0 0 0 0",
"output": "3"
},
{
"input": "100\n0 0 0 0 0 1 0",
"output": "6"
}
] | 1,664,227,552
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 49
| 92
| 0
|
n = int(input())
a = [int(x) for x in input().split()]
sm = 0
for i in a:
sm += i
if sm < n:
while(sm < n):
n -= sm
#print(n)
temp = 0
for i in range(7):
temp += a[i]
# print(temp)
if temp >= n:
print(i+1)
break
else:
temp = 0
for i in range(7):
temp += a[i]
if temp >= n:
print(i+1)
break
|
Title: Petr and Book
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One Sunday Petr went to a bookshop and bought a new book on sports programming. The book had exactly *n* pages.
Petr decided to start reading it starting from the next day, that is, from Monday. Petr's got a very tight schedule and for each day of the week he knows how many pages he will be able to read on that day. Some days are so busy that Petr will have no time to read whatsoever. However, we know that he will be able to read at least one page a week.
Assuming that Petr will not skip days and will read as much as he can every day, determine on which day of the week he will read the last page of the book.
Input Specification:
The first input line contains the single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of pages in the book.
The second line contains seven non-negative space-separated integers that do not exceed 1000 — those integers represent how many pages Petr can read on Monday, Tuesday, Wednesday, Thursday, Friday, Saturday and Sunday correspondingly. It is guaranteed that at least one of those numbers is larger than zero.
Output Specification:
Print a single number — the number of the day of the week, when Petr will finish reading the book. The days of the week are numbered starting with one in the natural order: Monday, Tuesday, Wednesday, Thursday, Friday, Saturday, Sunday.
Demo Input:
['100\n15 20 20 15 10 30 45\n', '2\n1 0 0 0 0 0 0\n']
Demo Output:
['6\n', '1\n']
Note:
Note to the first sample:
By the end of Monday and therefore, by the beginning of Tuesday Petr has 85 pages left. He has 65 pages left by Wednesday, 45 by Thursday, 30 by Friday, 20 by Saturday and on Saturday Petr finishes reading the book (and he also has time to read 10 pages of something else).
Note to the second sample:
On Monday of the first week Petr will read the first page. On Monday of the second week Petr will read the second page and will finish reading the book.
|
```python
n = int(input())
a = [int(x) for x in input().split()]
sm = 0
for i in a:
sm += i
if sm < n:
while(sm < n):
n -= sm
#print(n)
temp = 0
for i in range(7):
temp += a[i]
# print(temp)
if temp >= n:
print(i+1)
break
else:
temp = 0
for i in range(7):
temp += a[i]
if temp >= n:
print(i+1)
break
```
| 3
|
|
2
|
A
|
Winner
|
PROGRAMMING
| 1,500
|
[
"hashing",
"implementation"
] |
A. Winner
|
1
|
64
|
The winner of the card game popular in Berland "Berlogging" is determined according to the following rules. If at the end of the game there is only one player with the maximum number of points, he is the winner. The situation becomes more difficult if the number of such players is more than one. During each round a player gains or loses a particular number of points. In the course of the game the number of points is registered in the line "name score", where name is a player's name, and score is the number of points gained in this round, which is an integer number. If score is negative, this means that the player has lost in the round. So, if two or more players have the maximum number of points (say, it equals to *m*) at the end of the game, than wins the one of them who scored at least *m* points first. Initially each player has 0 points. It's guaranteed that at the end of the game at least one player has a positive number of points.
|
The first line contains an integer number *n* (1<=<=≤<=<=*n*<=<=≤<=<=1000), *n* is the number of rounds played. Then follow *n* lines, containing the information about the rounds in "name score" format in chronological order, where name is a string of lower-case Latin letters with the length from 1 to 32, and score is an integer number between -1000 and 1000, inclusive.
|
Print the name of the winner.
|
[
"3\nmike 3\nandrew 5\nmike 2\n",
"3\nandrew 3\nandrew 2\nmike 5\n"
] |
[
"andrew\n",
"andrew\n"
] |
none
| 0
|
[
{
"input": "3\nmike 3\nandrew 5\nmike 2",
"output": "andrew"
},
{
"input": "3\nandrew 3\nandrew 2\nmike 5",
"output": "andrew"
},
{
"input": "5\nkaxqybeultn -352\nmgochgrmeyieyskhuourfg -910\nkaxqybeultn 691\nmgochgrmeyieyskhuourfg -76\nkaxqybeultn -303",
"output": "kaxqybeultn"
},
{
"input": "7\nksjuuerbnlklcfdjeyq 312\ndthjlkrvvbyahttifpdewvyslsh -983\nksjuuerbnlklcfdjeyq 268\ndthjlkrvvbyahttifpdewvyslsh 788\nksjuuerbnlklcfdjeyq -79\nksjuuerbnlklcfdjeyq -593\nksjuuerbnlklcfdjeyq 734",
"output": "ksjuuerbnlklcfdjeyq"
},
{
"input": "12\natrtthfpcvishmqbakprquvnejr 185\natrtthfpcvishmqbakprquvnejr -699\natrtthfpcvishmqbakprquvnejr -911\natrtthfpcvishmqbakprquvnejr -220\nfcgslzkicjrpbqaifgweyzreajjfdo 132\nfcgslzkicjrpbqaifgweyzreajjfdo -242\nm 177\nm -549\natrtthfpcvishmqbakprquvnejr -242\nm 38\natrtthfpcvishmqbakprquvnejr -761\nfcgslzkicjrpbqaifgweyzreajjfdo 879",
"output": "fcgslzkicjrpbqaifgweyzreajjfdo"
},
{
"input": "15\naawtvezfntstrcpgbzjbf 681\nzhahpvqiptvksnbjkdvmknb -74\naawtvezfntstrcpgbzjbf 661\njpdwmyke 474\naawtvezfntstrcpgbzjbf -547\naawtvezfntstrcpgbzjbf 600\nzhahpvqiptvksnbjkdvmknb -11\njpdwmyke 711\nbjmj 652\naawtvezfntstrcpgbzjbf -1000\naawtvezfntstrcpgbzjbf -171\nbjmj -302\naawtvezfntstrcpgbzjbf 961\nzhahpvqiptvksnbjkdvmknb 848\nbjmj -735",
"output": "aawtvezfntstrcpgbzjbf"
},
{
"input": "17\nqdplghhx -649\nivhgbxiv 424\nivhgbxiv -72\nivhgbxiv 479\nugowfouebkelargxylsxn 83\nugowfouebkelargxylsxn -840\nivhgbxiv 382\nqdplghhx -904\nivhgbxiv -710\nugowfouebkelargxylsxn -838\nqdplghhx -974\nqdplghhx 571\nivhgbxiv -145\nugowfouebkelargxylsxn -788\nivhgbxiv 209\nivhgbxiv 420\nqdplghhx -158",
"output": "ivhgbxiv"
}
] | 1,670,241,704
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 5
| 122
| 0
|
n = int(input())
info = {}
maximum = 0
winner = ''
for i in range(n):
person, num = map(str,input().split())
info[person] = info.get(person, 0) + int(num)
if int(num) > 0:
if maximum < info[person]:
maximum = info[person]
winner = person
else:
for name in list(info.keys()):
if info[name] > info[person]:
winner = name
maximum = info[person]
print(winner)
|
Title: Winner
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
The winner of the card game popular in Berland "Berlogging" is determined according to the following rules. If at the end of the game there is only one player with the maximum number of points, he is the winner. The situation becomes more difficult if the number of such players is more than one. During each round a player gains or loses a particular number of points. In the course of the game the number of points is registered in the line "name score", where name is a player's name, and score is the number of points gained in this round, which is an integer number. If score is negative, this means that the player has lost in the round. So, if two or more players have the maximum number of points (say, it equals to *m*) at the end of the game, than wins the one of them who scored at least *m* points first. Initially each player has 0 points. It's guaranteed that at the end of the game at least one player has a positive number of points.
Input Specification:
The first line contains an integer number *n* (1<=<=≤<=<=*n*<=<=≤<=<=1000), *n* is the number of rounds played. Then follow *n* lines, containing the information about the rounds in "name score" format in chronological order, where name is a string of lower-case Latin letters with the length from 1 to 32, and score is an integer number between -1000 and 1000, inclusive.
Output Specification:
Print the name of the winner.
Demo Input:
['3\nmike 3\nandrew 5\nmike 2\n', '3\nandrew 3\nandrew 2\nmike 5\n']
Demo Output:
['andrew\n', 'andrew\n']
Note:
none
|
```python
n = int(input())
info = {}
maximum = 0
winner = ''
for i in range(n):
person, num = map(str,input().split())
info[person] = info.get(person, 0) + int(num)
if int(num) > 0:
if maximum < info[person]:
maximum = info[person]
winner = person
else:
for name in list(info.keys()):
if info[name] > info[person]:
winner = name
maximum = info[person]
print(winner)
```
| 0
|
149
|
A
|
Business trip
|
PROGRAMMING
| 900
|
[
"greedy",
"implementation",
"sortings"
] | null | null |
What joy! Petya's parents went on a business trip for the whole year and the playful kid is left all by himself. Petya got absolutely happy. He jumped on the bed and threw pillows all day long, until...
Today Petya opened the cupboard and found a scary note there. His parents had left him with duties: he should water their favourite flower all year, each day, in the morning, in the afternoon and in the evening. "Wait a second!" — thought Petya. He know for a fact that if he fulfills the parents' task in the *i*-th (1<=≤<=*i*<=≤<=12) month of the year, then the flower will grow by *a**i* centimeters, and if he doesn't water the flower in the *i*-th month, then the flower won't grow this month. Petya also knows that try as he might, his parents won't believe that he has been watering the flower if it grows strictly less than by *k* centimeters.
Help Petya choose the minimum number of months when he will water the flower, given that the flower should grow no less than by *k* centimeters.
|
The first line contains exactly one integer *k* (0<=≤<=*k*<=≤<=100). The next line contains twelve space-separated integers: the *i*-th (1<=≤<=*i*<=≤<=12) number in the line represents *a**i* (0<=≤<=*a**i*<=≤<=100).
|
Print the only integer — the minimum number of months when Petya has to water the flower so that the flower grows no less than by *k* centimeters. If the flower can't grow by *k* centimeters in a year, print -1.
|
[
"5\n1 1 1 1 2 2 3 2 2 1 1 1\n",
"0\n0 0 0 0 0 0 0 1 1 2 3 0\n",
"11\n1 1 4 1 1 5 1 1 4 1 1 1\n"
] |
[
"2\n",
"0\n",
"3\n"
] |
Let's consider the first sample test. There it is enough to water the flower during the seventh and the ninth month. Then the flower grows by exactly five centimeters.
In the second sample Petya's parents will believe him even if the flower doesn't grow at all (*k* = 0). So, it is possible for Petya not to water the flower at all.
| 500
|
[
{
"input": "5\n1 1 1 1 2 2 3 2 2 1 1 1",
"output": "2"
},
{
"input": "0\n0 0 0 0 0 0 0 1 1 2 3 0",
"output": "0"
},
{
"input": "11\n1 1 4 1 1 5 1 1 4 1 1 1",
"output": "3"
},
{
"input": "15\n20 1 1 1 1 2 2 1 2 2 1 1",
"output": "1"
},
{
"input": "7\n8 9 100 12 14 17 21 10 11 100 23 10",
"output": "1"
},
{
"input": "52\n1 12 3 11 4 5 10 6 9 7 8 2",
"output": "6"
},
{
"input": "50\n2 2 3 4 5 4 4 5 7 3 2 7",
"output": "-1"
},
{
"input": "0\n55 81 28 48 99 20 67 95 6 19 10 93",
"output": "0"
},
{
"input": "93\n85 40 93 66 92 43 61 3 64 51 90 21",
"output": "1"
},
{
"input": "99\n36 34 22 0 0 0 52 12 0 0 33 47",
"output": "2"
},
{
"input": "99\n28 32 31 0 10 35 11 18 0 0 32 28",
"output": "3"
},
{
"input": "99\n19 17 0 1 18 11 29 9 29 22 0 8",
"output": "4"
},
{
"input": "76\n2 16 11 10 12 0 20 4 4 14 11 14",
"output": "5"
},
{
"input": "41\n2 1 7 7 4 2 4 4 9 3 10 0",
"output": "6"
},
{
"input": "47\n8 2 2 4 3 1 9 4 2 7 7 8",
"output": "7"
},
{
"input": "58\n6 11 7 0 5 6 3 9 4 9 5 1",
"output": "8"
},
{
"input": "32\n5 2 4 1 5 0 5 1 4 3 0 3",
"output": "9"
},
{
"input": "31\n6 1 0 4 4 5 1 0 5 3 2 0",
"output": "9"
},
{
"input": "35\n2 3 0 0 6 3 3 4 3 5 0 6",
"output": "9"
},
{
"input": "41\n3 1 3 4 3 6 6 1 4 4 0 6",
"output": "11"
},
{
"input": "97\n0 5 3 12 10 16 22 8 21 17 21 10",
"output": "5"
},
{
"input": "100\n21 21 0 0 4 13 0 26 0 0 0 15",
"output": "6"
},
{
"input": "100\n0 0 16 5 22 0 5 0 25 0 14 13",
"output": "7"
},
{
"input": "97\n17 0 10 0 0 0 18 0 14 23 15 0",
"output": "6"
},
{
"input": "100\n0 9 0 18 7 0 0 14 33 3 0 16",
"output": "7"
},
{
"input": "95\n5 2 13 0 15 18 17 0 6 11 0 8",
"output": "9"
},
{
"input": "94\n11 13 0 9 15 8 8 16 3 7 1 3",
"output": "11"
},
{
"input": "96\n8 4 12 15 8 0 4 10 6 6 12 11",
"output": "11"
},
{
"input": "100\n5 5 3 8 6 5 0 3 3 8 1 3",
"output": "-1"
},
{
"input": "100\n1 0 0 1 1 0 1 1 1 1 2 1",
"output": "-1"
},
{
"input": "100\n6 3 2 0 4 1 2 2 2 2 1 1",
"output": "-1"
},
{
"input": "0\n0 0 0 0 0 0 0 0 0 0 0 0",
"output": "0"
},
{
"input": "100\n0 0 0 0 0 0 0 0 0 0 0 0",
"output": "-1"
},
{
"input": "0\n100 100 100 100 100 100 100 100 100 100 100 100",
"output": "0"
},
{
"input": "100\n100 100 100 100 100 100 100 100 100 100 100 100",
"output": "1"
},
{
"input": "12\n1 1 1 1 1 1 1 1 1 1 1 1",
"output": "12"
},
{
"input": "13\n1 1 1 1 1 1 1 1 1 1 1 2",
"output": "12"
},
{
"input": "15\n10 1 1 1 1 1 1 1 1 1 1 1",
"output": "6"
},
{
"input": "1\n0 0 0 0 0 0 0 0 0 0 0 0",
"output": "-1"
}
] | 1,637,451,124
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 35
| 92
| 0
|
k = int(input())
a = sorted(list(map(int, input().split())),reverse=True)
for i in range(12):
if sum(a[:i]) >= k:
print(i)
exit(0)
print(-1)
|
Title: Business trip
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
What joy! Petya's parents went on a business trip for the whole year and the playful kid is left all by himself. Petya got absolutely happy. He jumped on the bed and threw pillows all day long, until...
Today Petya opened the cupboard and found a scary note there. His parents had left him with duties: he should water their favourite flower all year, each day, in the morning, in the afternoon and in the evening. "Wait a second!" — thought Petya. He know for a fact that if he fulfills the parents' task in the *i*-th (1<=≤<=*i*<=≤<=12) month of the year, then the flower will grow by *a**i* centimeters, and if he doesn't water the flower in the *i*-th month, then the flower won't grow this month. Petya also knows that try as he might, his parents won't believe that he has been watering the flower if it grows strictly less than by *k* centimeters.
Help Petya choose the minimum number of months when he will water the flower, given that the flower should grow no less than by *k* centimeters.
Input Specification:
The first line contains exactly one integer *k* (0<=≤<=*k*<=≤<=100). The next line contains twelve space-separated integers: the *i*-th (1<=≤<=*i*<=≤<=12) number in the line represents *a**i* (0<=≤<=*a**i*<=≤<=100).
Output Specification:
Print the only integer — the minimum number of months when Petya has to water the flower so that the flower grows no less than by *k* centimeters. If the flower can't grow by *k* centimeters in a year, print -1.
Demo Input:
['5\n1 1 1 1 2 2 3 2 2 1 1 1\n', '0\n0 0 0 0 0 0 0 1 1 2 3 0\n', '11\n1 1 4 1 1 5 1 1 4 1 1 1\n']
Demo Output:
['2\n', '0\n', '3\n']
Note:
Let's consider the first sample test. There it is enough to water the flower during the seventh and the ninth month. Then the flower grows by exactly five centimeters.
In the second sample Petya's parents will believe him even if the flower doesn't grow at all (*k* = 0). So, it is possible for Petya not to water the flower at all.
|
```python
k = int(input())
a = sorted(list(map(int, input().split())),reverse=True)
for i in range(12):
if sum(a[:i]) >= k:
print(i)
exit(0)
print(-1)
```
| 0
|
|
1,011
|
A
|
Stages
|
PROGRAMMING
| 900
|
[
"greedy",
"implementation",
"sortings"
] | null | null |
Natasha is going to fly to Mars. She needs to build a rocket, which consists of several stages in some order. Each of the stages is defined by a lowercase Latin letter. This way, the rocket can be described by the string — concatenation of letters, which correspond to the stages.
There are $n$ stages available. The rocket must contain exactly $k$ of them. Stages in the rocket should be ordered by their weight. So, after the stage with some letter can go only stage with a letter, which is at least two positions after in the alphabet (skipping one letter in between, or even more). For example, after letter 'c' can't go letters 'a', 'b', 'c' and 'd', but can go letters 'e', 'f', ..., 'z'.
For the rocket to fly as far as possible, its weight should be minimal. The weight of the rocket is equal to the sum of the weights of its stages. The weight of the stage is the number of its letter in the alphabet. For example, the stage 'a 'weighs one ton,' b 'weighs two tons, and' z' — $26$ tons.
Build the rocket with the minimal weight or determine, that it is impossible to build a rocket at all. Each stage can be used at most once.
|
The first line of input contains two integers — $n$ and $k$ ($1 \le k \le n \le 50$) – the number of available stages and the number of stages to use in the rocket.
The second line contains string $s$, which consists of exactly $n$ lowercase Latin letters. Each letter defines a new stage, which can be used to build the rocket. Each stage can be used at most once.
|
Print a single integer — the minimal total weight of the rocket or -1, if it is impossible to build the rocket at all.
|
[
"5 3\nxyabd\n",
"7 4\nproblem\n",
"2 2\nab\n",
"12 1\nabaabbaaabbb\n"
] |
[
"29",
"34",
"-1",
"1"
] |
In the first example, the following rockets satisfy the condition:
- "adx" (weight is $1+4+24=29$);- "ady" (weight is $1+4+25=30$);- "bdx" (weight is $2+4+24=30$);- "bdy" (weight is $2+4+25=31$).
Rocket "adx" has the minimal weight, so the answer is $29$.
In the second example, target rocket is "belo". Its weight is $2+5+12+15=34$.
In the third example, $n=k=2$, so the rocket must have both stages: 'a' and 'b'. This rocket doesn't satisfy the condition, because these letters are adjacent in the alphabet. Answer is -1.
| 500
|
[
{
"input": "5 3\nxyabd",
"output": "29"
},
{
"input": "7 4\nproblem",
"output": "34"
},
{
"input": "2 2\nab",
"output": "-1"
},
{
"input": "12 1\nabaabbaaabbb",
"output": "1"
},
{
"input": "50 13\nqwertyuiopasdfghjklzxcvbnmaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "169"
},
{
"input": "50 14\nqwertyuiopasdfghjklzxcvbnmaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "-1"
},
{
"input": "1 1\na",
"output": "1"
},
{
"input": "50 1\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "1"
},
{
"input": "50 2\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "-1"
},
{
"input": "13 13\nuwgmkyqeiaocs",
"output": "169"
},
{
"input": "13 13\nhzdxpbfvrltnj",
"output": "182"
},
{
"input": "1 1\nn",
"output": "14"
},
{
"input": "10 8\nsmzeblyjqw",
"output": "113"
},
{
"input": "20 20\ntzmvhskkyugkuuxpvtbh",
"output": "-1"
},
{
"input": "30 15\nwjzolzzkfulwgioksfxmcxmnnjtoav",
"output": "-1"
},
{
"input": "40 30\nxumfrflllrrgswehqtsskefixhcxjrxbjmrpsshv",
"output": "-1"
},
{
"input": "50 31\nahbyyoxltryqdmvenemaqnbakglgqolxnaifnqtoclnnqiabpz",
"output": "-1"
},
{
"input": "10 7\niuiukrxcml",
"output": "99"
},
{
"input": "38 2\nvjzarfykmrsrvwbwfwldsulhxtykmjbnwmdufa",
"output": "5"
},
{
"input": "12 6\nfwseyrarkwcd",
"output": "61"
},
{
"input": "2 2\nac",
"output": "4"
},
{
"input": "1 1\nc",
"output": "3"
},
{
"input": "2 2\nad",
"output": "5"
},
{
"input": "2 1\nac",
"output": "1"
},
{
"input": "4 3\nadjz",
"output": "15"
},
{
"input": "3 3\naoz",
"output": "42"
},
{
"input": "3 1\nzzz",
"output": "26"
},
{
"input": "2 1\nxz",
"output": "24"
},
{
"input": "5 1\naaddd",
"output": "1"
}
] | 1,532,801,338
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 29
| 140
| 0
|
d = [False for i in range(26)]
n, k = map(int,input().split())
for el in str(input()):
d[ord(el) - ord("a")] = True
ans = 100000000000000
def get_ans(i):
if not d[i]:
return 100000000000000
last = i + 2
ret = i +1
gett = 1
for j in range(i + 2, 26):
if j >= last and d[j] and gett < k:
last = j + 2
ret += j +1
gett += 1
if gett != k:
return 100000000000000
return ret
for i in range(26):
ans = min(ans, get_ans(i))
print(- 1 if ans == 100000000000000 else ans)
|
Title: Stages
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Natasha is going to fly to Mars. She needs to build a rocket, which consists of several stages in some order. Each of the stages is defined by a lowercase Latin letter. This way, the rocket can be described by the string — concatenation of letters, which correspond to the stages.
There are $n$ stages available. The rocket must contain exactly $k$ of them. Stages in the rocket should be ordered by their weight. So, after the stage with some letter can go only stage with a letter, which is at least two positions after in the alphabet (skipping one letter in between, or even more). For example, after letter 'c' can't go letters 'a', 'b', 'c' and 'd', but can go letters 'e', 'f', ..., 'z'.
For the rocket to fly as far as possible, its weight should be minimal. The weight of the rocket is equal to the sum of the weights of its stages. The weight of the stage is the number of its letter in the alphabet. For example, the stage 'a 'weighs one ton,' b 'weighs two tons, and' z' — $26$ tons.
Build the rocket with the minimal weight or determine, that it is impossible to build a rocket at all. Each stage can be used at most once.
Input Specification:
The first line of input contains two integers — $n$ and $k$ ($1 \le k \le n \le 50$) – the number of available stages and the number of stages to use in the rocket.
The second line contains string $s$, which consists of exactly $n$ lowercase Latin letters. Each letter defines a new stage, which can be used to build the rocket. Each stage can be used at most once.
Output Specification:
Print a single integer — the minimal total weight of the rocket or -1, if it is impossible to build the rocket at all.
Demo Input:
['5 3\nxyabd\n', '7 4\nproblem\n', '2 2\nab\n', '12 1\nabaabbaaabbb\n']
Demo Output:
['29', '34', '-1', '1']
Note:
In the first example, the following rockets satisfy the condition:
- "adx" (weight is $1+4+24=29$);- "ady" (weight is $1+4+25=30$);- "bdx" (weight is $2+4+24=30$);- "bdy" (weight is $2+4+25=31$).
Rocket "adx" has the minimal weight, so the answer is $29$.
In the second example, target rocket is "belo". Its weight is $2+5+12+15=34$.
In the third example, $n=k=2$, so the rocket must have both stages: 'a' and 'b'. This rocket doesn't satisfy the condition, because these letters are adjacent in the alphabet. Answer is -1.
|
```python
d = [False for i in range(26)]
n, k = map(int,input().split())
for el in str(input()):
d[ord(el) - ord("a")] = True
ans = 100000000000000
def get_ans(i):
if not d[i]:
return 100000000000000
last = i + 2
ret = i +1
gett = 1
for j in range(i + 2, 26):
if j >= last and d[j] and gett < k:
last = j + 2
ret += j +1
gett += 1
if gett != k:
return 100000000000000
return ret
for i in range(26):
ans = min(ans, get_ans(i))
print(- 1 if ans == 100000000000000 else ans)
```
| 3
|
|
431
|
A
|
Black Square
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Quite recently, a very smart student named Jury decided that lectures are boring, so he downloaded a game called "Black Square" on his super cool touchscreen phone.
In this game, the phone's screen is divided into four vertical strips. Each second, a black square appears on some of the strips. According to the rules of the game, Jury must use this second to touch the corresponding strip to make the square go away. As Jury is both smart and lazy, he counted that he wastes exactly *a**i* calories on touching the *i*-th strip.
You've got a string *s*, describing the process of the game and numbers *a*1,<=*a*2,<=*a*3,<=*a*4. Calculate how many calories Jury needs to destroy all the squares?
|
The first line contains four space-separated integers *a*1, *a*2, *a*3, *a*4 (0<=≤<=*a*1,<=*a*2,<=*a*3,<=*a*4<=≤<=104).
The second line contains string *s* (1<=≤<=|*s*|<=≤<=105), where the *і*-th character of the string equals "1", if on the *i*-th second of the game the square appears on the first strip, "2", if it appears on the second strip, "3", if it appears on the third strip, "4", if it appears on the fourth strip.
|
Print a single integer — the total number of calories that Jury wastes.
|
[
"1 2 3 4\n123214\n",
"1 5 3 2\n11221\n"
] |
[
"13\n",
"13\n"
] |
none
| 500
|
[
{
"input": "1 2 3 4\n123214",
"output": "13"
},
{
"input": "1 5 3 2\n11221",
"output": "13"
},
{
"input": "5 5 5 1\n3422",
"output": "16"
},
{
"input": "4 3 2 1\n2",
"output": "3"
},
{
"input": "5651 6882 6954 4733\n2442313421",
"output": "60055"
},
{
"input": "0 0 0 0\n4132",
"output": "0"
},
{
"input": "3163 5778 83 7640\n11141442444",
"output": "64270"
},
{
"input": "1809 1302 7164 6122\n3144121413113111223311232232114144321414421243443243422322144324121433444342231344234443332241322442",
"output": "420780"
},
{
"input": "0 0 0 0\n1",
"output": "0"
},
{
"input": "1 2 3 4\n4",
"output": "4"
},
{
"input": "2343 7653 1242 5432\n1",
"output": "2343"
},
{
"input": "2343 7653 1242 5432\n2",
"output": "7653"
},
{
"input": "2343 7653 1242 5432\n3",
"output": "1242"
},
{
"input": "2343 7653 1242 5432\n4",
"output": "5432"
},
{
"input": "1 2 3 4\n123412",
"output": "13"
},
{
"input": "50 50 50 50\n11111111111111111111111111111111111111111111111111111",
"output": "2650"
},
{
"input": "1 2 3 4\n11111111111111111111111111111111111111111111111111",
"output": "50"
},
{
"input": "1 2 3 4\n23123231321231231231231231221232123121312321",
"output": "87"
},
{
"input": "1 2 3 4\n1111111111111222222222233333333333444444444444444",
"output": "126"
},
{
"input": "2 3 1 4\n121321232412342112312313213123123412131231231232",
"output": "105"
}
] | 1,654,455,113
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 49
| 61
| 102,400
|
n=input()
sq=input()
n=list(map(int,n.split()))
calo=0
for i in sq:
if i=="1":
calo+=n[0]
elif i=="2":
calo+=n[1]
elif i=="3":
calo+=n[2]
elif i=="4":
calo+=n[3]
print(calo)
|
Title: Black Square
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Quite recently, a very smart student named Jury decided that lectures are boring, so he downloaded a game called "Black Square" on his super cool touchscreen phone.
In this game, the phone's screen is divided into four vertical strips. Each second, a black square appears on some of the strips. According to the rules of the game, Jury must use this second to touch the corresponding strip to make the square go away. As Jury is both smart and lazy, he counted that he wastes exactly *a**i* calories on touching the *i*-th strip.
You've got a string *s*, describing the process of the game and numbers *a*1,<=*a*2,<=*a*3,<=*a*4. Calculate how many calories Jury needs to destroy all the squares?
Input Specification:
The first line contains four space-separated integers *a*1, *a*2, *a*3, *a*4 (0<=≤<=*a*1,<=*a*2,<=*a*3,<=*a*4<=≤<=104).
The second line contains string *s* (1<=≤<=|*s*|<=≤<=105), where the *і*-th character of the string equals "1", if on the *i*-th second of the game the square appears on the first strip, "2", if it appears on the second strip, "3", if it appears on the third strip, "4", if it appears on the fourth strip.
Output Specification:
Print a single integer — the total number of calories that Jury wastes.
Demo Input:
['1 2 3 4\n123214\n', '1 5 3 2\n11221\n']
Demo Output:
['13\n', '13\n']
Note:
none
|
```python
n=input()
sq=input()
n=list(map(int,n.split()))
calo=0
for i in sq:
if i=="1":
calo+=n[0]
elif i=="2":
calo+=n[1]
elif i=="3":
calo+=n[2]
elif i=="4":
calo+=n[3]
print(calo)
```
| 3
|
|
118
|
A
|
String Task
|
PROGRAMMING
| 1,000
|
[
"implementation",
"strings"
] | null | null |
Petya started to attend programming lessons. On the first lesson his task was to write a simple program. The program was supposed to do the following: in the given string, consisting if uppercase and lowercase Latin letters, it:
- deletes all the vowels, - inserts a character "." before each consonant, - replaces all uppercase consonants with corresponding lowercase ones.
Vowels are letters "A", "O", "Y", "E", "U", "I", and the rest are consonants. The program's input is exactly one string, it should return the output as a single string, resulting after the program's processing the initial string.
Help Petya cope with this easy task.
|
The first line represents input string of Petya's program. This string only consists of uppercase and lowercase Latin letters and its length is from 1 to 100, inclusive.
|
Print the resulting string. It is guaranteed that this string is not empty.
|
[
"tour\n",
"Codeforces\n",
"aBAcAba\n"
] |
[
".t.r\n",
".c.d.f.r.c.s\n",
".b.c.b\n"
] |
none
| 500
|
[
{
"input": "tour",
"output": ".t.r"
},
{
"input": "Codeforces",
"output": ".c.d.f.r.c.s"
},
{
"input": "aBAcAba",
"output": ".b.c.b"
},
{
"input": "obn",
"output": ".b.n"
},
{
"input": "wpwl",
"output": ".w.p.w.l"
},
{
"input": "ggdvq",
"output": ".g.g.d.v.q"
},
{
"input": "pumesz",
"output": ".p.m.s.z"
},
{
"input": "g",
"output": ".g"
},
{
"input": "zjuotps",
"output": ".z.j.t.p.s"
},
{
"input": "jzbwuehe",
"output": ".j.z.b.w.h"
},
{
"input": "tnkgwuugu",
"output": ".t.n.k.g.w.g"
},
{
"input": "kincenvizh",
"output": ".k.n.c.n.v.z.h"
},
{
"input": "xattxjenual",
"output": ".x.t.t.x.j.n.l"
},
{
"input": "ktajqhpqsvhw",
"output": ".k.t.j.q.h.p.q.s.v.h.w"
},
{
"input": "xnhcigytnqcmy",
"output": ".x.n.h.c.g.t.n.q.c.m"
},
{
"input": "jfmtbejyilxcec",
"output": ".j.f.m.t.b.j.l.x.c.c"
},
{
"input": "D",
"output": ".d"
},
{
"input": "ab",
"output": ".b"
},
{
"input": "Ab",
"output": ".b"
},
{
"input": "aB",
"output": ".b"
},
{
"input": "AB",
"output": ".b"
},
{
"input": "ba",
"output": ".b"
},
{
"input": "bA",
"output": ".b"
},
{
"input": "Ba",
"output": ".b"
},
{
"input": "BA",
"output": ".b"
},
{
"input": "aab",
"output": ".b"
},
{
"input": "baa",
"output": ".b"
},
{
"input": "femOZeCArKCpUiHYnbBPTIOFmsHmcpObtPYcLCdjFrUMIyqYzAokKUiiKZRouZiNMoiOuGVoQzaaCAOkquRjmmKKElLNqCnhGdQM",
"output": ".f.m.z.c.r.k.c.p.h.n.b.b.p.t.f.m.s.h.m.c.p.b.t.p.c.l.c.d.j.f.r.m.q.z.k.k.k.z.r.z.n.m.g.v.q.z.c.k.q.r.j.m.m.k.k.l.l.n.q.c.n.h.g.d.q.m"
},
{
"input": "VMBPMCmMDCLFELLIISUJDWQRXYRDGKMXJXJHXVZADRZWVWJRKFRRNSAWKKDPZZLFLNSGUNIVJFBEQsMDHSBJVDTOCSCgZWWKvZZN",
"output": ".v.m.b.p.m.c.m.m.d.c.l.f.l.l.s.j.d.w.q.r.x.r.d.g.k.m.x.j.x.j.h.x.v.z.d.r.z.w.v.w.j.r.k.f.r.r.n.s.w.k.k.d.p.z.z.l.f.l.n.s.g.n.v.j.f.b.q.s.m.d.h.s.b.j.v.d.t.c.s.c.g.z.w.w.k.v.z.z.n"
},
{
"input": "MCGFQQJNUKuAEXrLXibVjClSHjSxmlkQGTKZrRaDNDomIPOmtSgjJAjNVIVLeUGUAOHNkCBwNObVCHOWvNkLFQQbFnugYVMkJruJ",
"output": ".m.c.g.f.q.q.j.n.k.x.r.l.x.b.v.j.c.l.s.h.j.s.x.m.l.k.q.g.t.k.z.r.r.d.n.d.m.p.m.t.s.g.j.j.j.n.v.v.l.g.h.n.k.c.b.w.n.b.v.c.h.w.v.n.k.l.f.q.q.b.f.n.g.v.m.k.j.r.j"
},
{
"input": "iyaiuiwioOyzUaOtAeuEYcevvUyveuyioeeueoeiaoeiavizeeoeyYYaaAOuouueaUioueauayoiuuyiuovyOyiyoyioaoyuoyea",
"output": ".w.z.t.c.v.v.v.v.z.v"
},
{
"input": "yjnckpfyLtzwjsgpcrgCfpljnjwqzgVcufnOvhxplvflxJzqxnhrwgfJmPzifgubvspffmqrwbzivatlmdiBaddiaktdsfPwsevl",
"output": ".j.n.c.k.p.f.l.t.z.w.j.s.g.p.c.r.g.c.f.p.l.j.n.j.w.q.z.g.v.c.f.n.v.h.x.p.l.v.f.l.x.j.z.q.x.n.h.r.w.g.f.j.m.p.z.f.g.b.v.s.p.f.f.m.q.r.w.b.z.v.t.l.m.d.b.d.d.k.t.d.s.f.p.w.s.v.l"
},
{
"input": "RIIIUaAIYJOiuYIUWFPOOAIuaUEZeIooyUEUEAoIyIHYOEAlVAAIiLUAUAeiUIEiUMuuOiAgEUOIAoOUYYEYFEoOIIVeOOAOIIEg",
"output": ".r.j.w.f.p.z.h.l.v.l.m.g.f.v.g"
},
{
"input": "VBKQCFBMQHDMGNSGBQVJTGQCNHHRJMNKGKDPPSQRRVQTZNKBZGSXBPBRXPMVFTXCHZMSJVBRNFNTHBHGJLMDZJSVPZZBCCZNVLMQ",
"output": ".v.b.k.q.c.f.b.m.q.h.d.m.g.n.s.g.b.q.v.j.t.g.q.c.n.h.h.r.j.m.n.k.g.k.d.p.p.s.q.r.r.v.q.t.z.n.k.b.z.g.s.x.b.p.b.r.x.p.m.v.f.t.x.c.h.z.m.s.j.v.b.r.n.f.n.t.h.b.h.g.j.l.m.d.z.j.s.v.p.z.z.b.c.c.z.n.v.l.m.q"
},
{
"input": "iioyoaayeuyoolyiyoeuouiayiiuyTueyiaoiueyioiouyuauouayyiaeoeiiigmioiououeieeeyuyyaYyioiiooaiuouyoeoeg",
"output": ".l.t.g.m.g"
},
{
"input": "ueyiuiauuyyeueykeioouiiauzoyoeyeuyiaoaiiaaoaueyaeydaoauexuueafouiyioueeaaeyoeuaueiyiuiaeeayaioeouiuy",
"output": ".k.z.d.x.f"
},
{
"input": "FSNRBXLFQHZXGVMKLQDVHWLDSLKGKFMDRQWMWSSKPKKQBNDZRSCBLRSKCKKFFKRDMZFZGCNSMXNPMZVDLKXGNXGZQCLRTTDXLMXQ",
"output": ".f.s.n.r.b.x.l.f.q.h.z.x.g.v.m.k.l.q.d.v.h.w.l.d.s.l.k.g.k.f.m.d.r.q.w.m.w.s.s.k.p.k.k.q.b.n.d.z.r.s.c.b.l.r.s.k.c.k.k.f.f.k.r.d.m.z.f.z.g.c.n.s.m.x.n.p.m.z.v.d.l.k.x.g.n.x.g.z.q.c.l.r.t.t.d.x.l.m.x.q"
},
{
"input": "EYAYAYIOIOYOOAUOEUEUOUUYIYUUMOEOIIIAOIUOAAOIYOIOEUIERCEYYAOIOIGYUIAOYUEOEUAEAYPOYEYUUAUOAOEIYIEYUEEY",
"output": ".m.r.c.g.p"
},
{
"input": "jvvzcdcxjstbbksmqjsngxkgtttdxrljjxtwptgwwqzpvqchvgrkqlzxmptzblxhhsmrkmzzmgdfskhtmmnqzzflpmqdctvrfgtx",
"output": ".j.v.v.z.c.d.c.x.j.s.t.b.b.k.s.m.q.j.s.n.g.x.k.g.t.t.t.d.x.r.l.j.j.x.t.w.p.t.g.w.w.q.z.p.v.q.c.h.v.g.r.k.q.l.z.x.m.p.t.z.b.l.x.h.h.s.m.r.k.m.z.z.m.g.d.f.s.k.h.t.m.m.n.q.z.z.f.l.p.m.q.d.c.t.v.r.f.g.t.x"
},
{
"input": "YB",
"output": ".b"
},
{
"input": "fly",
"output": ".f.l"
},
{
"input": "YyyYYYyyYxdwdawdDAWDdaddYYYY",
"output": ".x.d.w.d.w.d.d.w.d.d.d.d"
}
] | 1,695,107,498
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 42
| 92
| 0
|
i = input()
set_list = list(i.lower())
v = ["a","o","y","e","u","i"]
u = [x for x in set_list if x not in v]
u_str = '.'.join(u)
u_str = '.' + u_str
print(u_str)
|
Title: String Task
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Petya started to attend programming lessons. On the first lesson his task was to write a simple program. The program was supposed to do the following: in the given string, consisting if uppercase and lowercase Latin letters, it:
- deletes all the vowels, - inserts a character "." before each consonant, - replaces all uppercase consonants with corresponding lowercase ones.
Vowels are letters "A", "O", "Y", "E", "U", "I", and the rest are consonants. The program's input is exactly one string, it should return the output as a single string, resulting after the program's processing the initial string.
Help Petya cope with this easy task.
Input Specification:
The first line represents input string of Petya's program. This string only consists of uppercase and lowercase Latin letters and its length is from 1 to 100, inclusive.
Output Specification:
Print the resulting string. It is guaranteed that this string is not empty.
Demo Input:
['tour\n', 'Codeforces\n', 'aBAcAba\n']
Demo Output:
['.t.r\n', '.c.d.f.r.c.s\n', '.b.c.b\n']
Note:
none
|
```python
i = input()
set_list = list(i.lower())
v = ["a","o","y","e","u","i"]
u = [x for x in set_list if x not in v]
u_str = '.'.join(u)
u_str = '.' + u_str
print(u_str)
```
| 3
|
|
460
|
A
|
Vasya and Socks
|
PROGRAMMING
| 900
|
[
"brute force",
"implementation",
"math"
] | null | null |
Vasya has *n* pairs of socks. In the morning of each day Vasya has to put on a pair of socks before he goes to school. When he comes home in the evening, Vasya takes off the used socks and throws them away. Every *m*-th day (at days with numbers *m*,<=2*m*,<=3*m*,<=...) mom buys a pair of socks to Vasya. She does it late in the evening, so that Vasya cannot put on a new pair of socks before the next day. How many consecutive days pass until Vasya runs out of socks?
|
The single line contains two integers *n* and *m* (1<=≤<=*n*<=≤<=100; 2<=≤<=*m*<=≤<=100), separated by a space.
|
Print a single integer — the answer to the problem.
|
[
"2 2\n",
"9 3\n"
] |
[
"3\n",
"13\n"
] |
In the first sample Vasya spends the first two days wearing the socks that he had initially. Then on day three he puts on the socks that were bought on day two.
In the second sample Vasya spends the first nine days wearing the socks that he had initially. Then he spends three days wearing the socks that were bought on the third, sixth and ninth days. Than he spends another day wearing the socks that were bought on the twelfth day.
| 500
|
[
{
"input": "2 2",
"output": "3"
},
{
"input": "9 3",
"output": "13"
},
{
"input": "1 2",
"output": "1"
},
{
"input": "2 3",
"output": "2"
},
{
"input": "1 99",
"output": "1"
},
{
"input": "4 4",
"output": "5"
},
{
"input": "10 2",
"output": "19"
},
{
"input": "10 9",
"output": "11"
},
{
"input": "100 100",
"output": "101"
},
{
"input": "2 27",
"output": "2"
},
{
"input": "99 100",
"output": "99"
},
{
"input": "99 2",
"output": "197"
},
{
"input": "100 3",
"output": "149"
},
{
"input": "98 3",
"output": "146"
},
{
"input": "4 4",
"output": "5"
},
{
"input": "100 2",
"output": "199"
},
{
"input": "62 4",
"output": "82"
},
{
"input": "99 10",
"output": "109"
},
{
"input": "100 5",
"output": "124"
},
{
"input": "80 80",
"output": "81"
},
{
"input": "95 16",
"output": "101"
},
{
"input": "75 16",
"output": "79"
},
{
"input": "99 74",
"output": "100"
},
{
"input": "20 21",
"output": "20"
},
{
"input": "52 96",
"output": "52"
},
{
"input": "24 5",
"output": "29"
}
] | 1,689,220,552
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 1
| 46
| 0
|
m, n = [int(i) for i in input().split()]
count = m
while True:
m//=n
count+=m
if m==0:
break
if m%n==0:
count+=1
if count%n==0:
print(count-1)
else:
print(count)
|
Title: Vasya and Socks
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya has *n* pairs of socks. In the morning of each day Vasya has to put on a pair of socks before he goes to school. When he comes home in the evening, Vasya takes off the used socks and throws them away. Every *m*-th day (at days with numbers *m*,<=2*m*,<=3*m*,<=...) mom buys a pair of socks to Vasya. She does it late in the evening, so that Vasya cannot put on a new pair of socks before the next day. How many consecutive days pass until Vasya runs out of socks?
Input Specification:
The single line contains two integers *n* and *m* (1<=≤<=*n*<=≤<=100; 2<=≤<=*m*<=≤<=100), separated by a space.
Output Specification:
Print a single integer — the answer to the problem.
Demo Input:
['2 2\n', '9 3\n']
Demo Output:
['3\n', '13\n']
Note:
In the first sample Vasya spends the first two days wearing the socks that he had initially. Then on day three he puts on the socks that were bought on day two.
In the second sample Vasya spends the first nine days wearing the socks that he had initially. Then he spends three days wearing the socks that were bought on the third, sixth and ninth days. Than he spends another day wearing the socks that were bought on the twelfth day.
|
```python
m, n = [int(i) for i in input().split()]
count = m
while True:
m//=n
count+=m
if m==0:
break
if m%n==0:
count+=1
if count%n==0:
print(count-1)
else:
print(count)
```
| 0
|
|
939
|
A
|
Love Triangle
|
PROGRAMMING
| 800
|
[
"graphs"
] | null | null |
As you could know there are no male planes nor female planes. However, each plane on Earth likes some other plane. There are *n* planes on Earth, numbered from 1 to *n*, and the plane with number *i* likes the plane with number *f**i*, where 1<=≤<=*f**i*<=≤<=*n* and *f**i*<=≠<=*i*.
We call a love triangle a situation in which plane *A* likes plane *B*, plane *B* likes plane *C* and plane *C* likes plane *A*. Find out if there is any love triangle on Earth.
|
The first line contains a single integer *n* (2<=≤<=*n*<=≤<=5000) — the number of planes.
The second line contains *n* integers *f*1,<=*f*2,<=...,<=*f**n* (1<=≤<=*f**i*<=≤<=*n*, *f**i*<=≠<=*i*), meaning that the *i*-th plane likes the *f**i*-th.
|
Output «YES» if there is a love triangle consisting of planes on Earth. Otherwise, output «NO».
You can output any letter in lower case or in upper case.
|
[
"5\n2 4 5 1 3\n",
"5\n5 5 5 5 1\n"
] |
[
"YES\n",
"NO\n"
] |
In first example plane 2 likes plane 4, plane 4 likes plane 1, plane 1 likes plane 2 and that is a love triangle.
In second example there are no love triangles.
| 500
|
[
{
"input": "5\n2 4 5 1 3",
"output": "YES"
},
{
"input": "5\n5 5 5 5 1",
"output": "NO"
},
{
"input": "3\n3 1 2",
"output": "YES"
},
{
"input": "10\n4 10 9 5 3 1 5 10 6 4",
"output": "NO"
},
{
"input": "10\n5 5 4 9 10 9 9 5 3 1",
"output": "YES"
},
{
"input": "100\n50 40 60 87 39 58 44 84 46 68 16 57 77 87 92 95 42 31 74 15 36 84 30 3 47 15 87 90 76 66 6 63 74 19 40 49 6 84 41 9 77 34 7 12 11 73 58 24 81 14 81 29 65 100 1 85 64 32 38 4 54 67 32 81 80 7 100 71 29 80 4 52 47 7 78 56 52 75 81 37 16 41 27 28 58 60 62 47 29 40 37 14 59 91 12 54 25 58 12 43",
"output": "NO"
},
{
"input": "100\n25 6 46 37 87 99 70 31 46 12 94 40 87 56 28 8 94 39 13 12 67 13 71 39 83 48 40 14 62 41 16 71 20 41 83 41 68 98 23 82 62 83 62 35 49 22 31 21 66 98 54 39 34 52 11 28 47 89 25 44 68 36 91 46 82 86 88 48 27 93 7 9 53 36 16 100 84 84 44 25 58 66 16 46 72 21 91 78 4 17 44 17 47 67 93 89 75 44 56 50",
"output": "YES"
},
{
"input": "2\n2 1",
"output": "NO"
},
{
"input": "3\n2 3 1",
"output": "YES"
},
{
"input": "5\n2 1 4 5 3",
"output": "YES"
},
{
"input": "5\n5 4 5 5 2",
"output": "YES"
}
] | 1,625,072,469
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 3
| 62
| 0
|
n=int(input())
f=[int(f) for f in input().split()]
s=set(f)
print("YES") if len(s)>=3 else print("NO")
|
Title: Love Triangle
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
As you could know there are no male planes nor female planes. However, each plane on Earth likes some other plane. There are *n* planes on Earth, numbered from 1 to *n*, and the plane with number *i* likes the plane with number *f**i*, where 1<=≤<=*f**i*<=≤<=*n* and *f**i*<=≠<=*i*.
We call a love triangle a situation in which plane *A* likes plane *B*, plane *B* likes plane *C* and plane *C* likes plane *A*. Find out if there is any love triangle on Earth.
Input Specification:
The first line contains a single integer *n* (2<=≤<=*n*<=≤<=5000) — the number of planes.
The second line contains *n* integers *f*1,<=*f*2,<=...,<=*f**n* (1<=≤<=*f**i*<=≤<=*n*, *f**i*<=≠<=*i*), meaning that the *i*-th plane likes the *f**i*-th.
Output Specification:
Output «YES» if there is a love triangle consisting of planes on Earth. Otherwise, output «NO».
You can output any letter in lower case or in upper case.
Demo Input:
['5\n2 4 5 1 3\n', '5\n5 5 5 5 1\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In first example plane 2 likes plane 4, plane 4 likes plane 1, plane 1 likes plane 2 and that is a love triangle.
In second example there are no love triangles.
|
```python
n=int(input())
f=[int(f) for f in input().split()]
s=set(f)
print("YES") if len(s)>=3 else print("NO")
```
| 0
|
|
615
|
D
|
Multipliers
|
PROGRAMMING
| 2,000
|
[
"math",
"number theory"
] | null | null |
Ayrat has number *n*, represented as it's prime factorization *p**i* of size *m*, i.e. *n*<==<=*p*1·*p*2·...·*p**m*. Ayrat got secret information that that the product of all divisors of *n* taken modulo 109<=+<=7 is the password to the secret data base. Now he wants to calculate this value.
|
The first line of the input contains a single integer *m* (1<=≤<=*m*<=≤<=200<=000) — the number of primes in factorization of *n*.
The second line contains *m* primes numbers *p**i* (2<=≤<=*p**i*<=≤<=200<=000).
|
Print one integer — the product of all divisors of *n* modulo 109<=+<=7.
|
[
"2\n2 3\n",
"3\n2 3 2\n"
] |
[
"36\n",
"1728\n"
] |
In the first sample *n* = 2·3 = 6. The divisors of 6 are 1, 2, 3 and 6, their product is equal to 1·2·3·6 = 36.
In the second sample 2·3·2 = 12. The divisors of 12 are 1, 2, 3, 4, 6 and 12. 1·2·3·4·6·12 = 1728.
| 2,000
|
[
{
"input": "2\n2 3",
"output": "36"
},
{
"input": "3\n2 3 2",
"output": "1728"
},
{
"input": "1\n2017",
"output": "2017"
},
{
"input": "2\n63997 63997",
"output": "135893224"
},
{
"input": "5\n11 7 11 7 11",
"output": "750455957"
},
{
"input": "5\n2 2 2 2 2",
"output": "32768"
},
{
"input": "4\n3 3 3 5",
"output": "332150625"
},
{
"input": "6\n101 103 107 109 101 103",
"output": "760029909"
},
{
"input": "10\n3 3 3 3 3 3 3 3 3 3",
"output": "555340537"
},
{
"input": "5\n7 5 2 3 13",
"output": "133580280"
},
{
"input": "23\n190979 191627 93263 72367 52561 188317 198397 24979 70313 105239 86263 78697 6163 7673 84137 199967 14657 84391 101009 16231 175103 24239 123289",
"output": "727083628"
},
{
"input": "7\n34429 104287 171293 101333 104287 34429 104287",
"output": "249330396"
},
{
"input": "27\n151153 29429 91411 91411 194507 194819 91411 91411 194507 181211 194507 131363 9371 194819 181211 194507 151153 91411 91411 192391 192391 151153 151153 194507 192391 192391 194819",
"output": "132073405"
},
{
"input": "47\n9041 60013 53609 82939 160861 123377 74383 74383 184039 19867 123377 101879 74383 193603 123377 115331 101879 53609 74383 115331 51869 51869 184039 193603 91297 160861 160861 115331 184039 51869 123377 74383 160861 74383 115331 115331 51869 74383 19867 193603 193603 115331 184039 9041 53609 53609 193603",
"output": "648634399"
},
{
"input": "67\n98929 19079 160079 181891 17599 91807 19079 98929 182233 92647 77477 98929 98639 182233 181891 182233 160079 98929 19079 98639 114941 98929 161341 91807 160079 22777 132361 92647 98929 77477 182233 103913 160079 77477 55711 77477 77477 182233 114941 91807 98929 19079 104393 182233 182233 131009 132361 16883 161341 103913 16883 98929 182233 114941 92647 92647 104393 132361 181891 114941 19079 91807 114941 132361 98639 161341 182233",
"output": "5987226"
},
{
"input": "44\n73 59 17 41 37 7 71 47 29 83 67 17 53 61 43 43 3 23 29 11 7 83 61 79 31 37 37 83 41 71 11 19 83 2 83 73 7 67 83 13 2 53 31 47",
"output": "464170294"
},
{
"input": "100\n2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199 211 223 227 229 233 239 241 251 257 263 269 271 277 281 283 293 307 311 313 317 331 337 347 349 353 359 367 373 379 383 389 397 401 409 419 421 431 433 439 443 449 457 461 463 467 479 487 491 499 503 509 521 523 541",
"output": "72902143"
},
{
"input": "130\n2 2 2 2 2 2 2 2 2 2 3 3 3 3 3 3 3 3 3 3 5 5 5 5 5 5 5 5 5 5 7 7 7 7 7 7 7 7 7 7 11 11 11 11 11 11 11 11 11 11 13 13 13 13 13 13 13 13 13 13 17 17 17 17 17 17 17 17 17 17 19 19 19 19 19 19 19 19 19 19 23 23 23 23 23 23 23 23 23 23 29 29 29 29 29 29 29 29 29 29 31 31 31 31 31 31 31 31 31 31 37 37 37 37 37 37 37 37 37 37 41 41 41 41 41 41 41 41 41 41",
"output": "869075922"
},
{
"input": "101\n2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199 211 223 227 229 233 239 241 251 257 263 269 271 277 281 283 293 307 311 313 317 331 337 347 349 353 359 367 373 379 383 389 397 401 409 419 421 431 433 439 443 449 457 461 463 467 479 487 491 499 503 509 521 523 541 2",
"output": "918713851"
},
{
"input": "42\n1657 1871 2423 3037 5023 5099 5449 5701 6361 6619 7393 7489 8179 9743 9791 9907 12289 12457 13063 13933 14947 16141 16829 16943 17191 17863 20161 20947 21661 22727 23197 23201 23813 24023 24181 24223 24391 26479 28619 30529 32441 32611",
"output": "468186759"
}
] | 1,681,405,234
| 2,434
|
PyPy 3
|
RUNTIME_ERROR
|
TESTS
| 8
| 108
| 2,662,400
|
import sys, os, io
input = io.BytesIO(os.read(0, os.fstat(0).st_size)).readline
def pow(x, y, mod):
if x == -1:
return 1 - y % 2 * 2
ans, u = 1, x
while y:
if y & 1:
ans = ans * u % mod
y >>= 1
u = u * u % mod
return ans
m = int(input())
mod = 10 ** 9 + 7
p = list(map(int, input().split()))
l = max(p) + 5
cnt = [0] * l
for i in p:
cnt[i] += 1
u, v = [], []
for i in range(l):
if cnt[i]:
u.append(cnt[i])
v.append(i)
l0, r0 = [1], [1]
for i in u:
l0.append(l0[-1] * (i + 1) % (mod - 1))
for i in u[::-1]:
r0.append(r0[-1] * (i + 1) % (mod - 1))
r0.reverse()
inv = [-1] * l
ans = 1
for i in range(len(u)):
ui, vi = u[i], v[i]
if inv[ui + 1] == -1:
inv[ui + 1] = pow(ui + 1, mod - 2, mod)
c = ui * (ui + 1) // 2 % (mod - 1)
x = l0[i] * r0[i + 1] % (mod - 1)
ans = ans * pow(vi, x * c % (mod - 1), mod) % mod
print(ans)
|
Title: Multipliers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Ayrat has number *n*, represented as it's prime factorization *p**i* of size *m*, i.e. *n*<==<=*p*1·*p*2·...·*p**m*. Ayrat got secret information that that the product of all divisors of *n* taken modulo 109<=+<=7 is the password to the secret data base. Now he wants to calculate this value.
Input Specification:
The first line of the input contains a single integer *m* (1<=≤<=*m*<=≤<=200<=000) — the number of primes in factorization of *n*.
The second line contains *m* primes numbers *p**i* (2<=≤<=*p**i*<=≤<=200<=000).
Output Specification:
Print one integer — the product of all divisors of *n* modulo 109<=+<=7.
Demo Input:
['2\n2 3\n', '3\n2 3 2\n']
Demo Output:
['36\n', '1728\n']
Note:
In the first sample *n* = 2·3 = 6. The divisors of 6 are 1, 2, 3 and 6, their product is equal to 1·2·3·6 = 36.
In the second sample 2·3·2 = 12. The divisors of 12 are 1, 2, 3, 4, 6 and 12. 1·2·3·4·6·12 = 1728.
|
```python
import sys, os, io
input = io.BytesIO(os.read(0, os.fstat(0).st_size)).readline
def pow(x, y, mod):
if x == -1:
return 1 - y % 2 * 2
ans, u = 1, x
while y:
if y & 1:
ans = ans * u % mod
y >>= 1
u = u * u % mod
return ans
m = int(input())
mod = 10 ** 9 + 7
p = list(map(int, input().split()))
l = max(p) + 5
cnt = [0] * l
for i in p:
cnt[i] += 1
u, v = [], []
for i in range(l):
if cnt[i]:
u.append(cnt[i])
v.append(i)
l0, r0 = [1], [1]
for i in u:
l0.append(l0[-1] * (i + 1) % (mod - 1))
for i in u[::-1]:
r0.append(r0[-1] * (i + 1) % (mod - 1))
r0.reverse()
inv = [-1] * l
ans = 1
for i in range(len(u)):
ui, vi = u[i], v[i]
if inv[ui + 1] == -1:
inv[ui + 1] = pow(ui + 1, mod - 2, mod)
c = ui * (ui + 1) // 2 % (mod - 1)
x = l0[i] * r0[i + 1] % (mod - 1)
ans = ans * pow(vi, x * c % (mod - 1), mod) % mod
print(ans)
```
| -1
|
|
677
|
A
|
Vanya and Fence
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Vanya and his friends are walking along the fence of height *h* and they do not want the guard to notice them. In order to achieve this the height of each of the friends should not exceed *h*. If the height of some person is greater than *h* he can bend down and then he surely won't be noticed by the guard. The height of the *i*-th person is equal to *a**i*.
Consider the width of the person walking as usual to be equal to 1, while the width of the bent person is equal to 2. Friends want to talk to each other while walking, so they would like to walk in a single row. What is the minimum width of the road, such that friends can walk in a row and remain unattended by the guard?
|
The first line of the input contains two integers *n* and *h* (1<=≤<=*n*<=≤<=1000, 1<=≤<=*h*<=≤<=1000) — the number of friends and the height of the fence, respectively.
The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=2*h*), the *i*-th of them is equal to the height of the *i*-th person.
|
Print a single integer — the minimum possible valid width of the road.
|
[
"3 7\n4 5 14\n",
"6 1\n1 1 1 1 1 1\n",
"6 5\n7 6 8 9 10 5\n"
] |
[
"4\n",
"6\n",
"11\n"
] |
In the first sample, only person number 3 must bend down, so the required width is equal to 1 + 1 + 2 = 4.
In the second sample, all friends are short enough and no one has to bend, so the width 1 + 1 + 1 + 1 + 1 + 1 = 6 is enough.
In the third sample, all the persons have to bend, except the last one. The required minimum width of the road is equal to 2 + 2 + 2 + 2 + 2 + 1 = 11.
| 500
|
[
{
"input": "3 7\n4 5 14",
"output": "4"
},
{
"input": "6 1\n1 1 1 1 1 1",
"output": "6"
},
{
"input": "6 5\n7 6 8 9 10 5",
"output": "11"
},
{
"input": "10 420\n214 614 297 675 82 740 174 23 255 15",
"output": "13"
},
{
"input": "10 561\n657 23 1096 487 785 66 481 554 1000 821",
"output": "15"
},
{
"input": "100 342\n478 143 359 336 162 333 385 515 117 496 310 538 469 539 258 676 466 677 1 296 150 560 26 213 627 221 255 126 617 174 279 178 24 435 70 145 619 46 669 566 300 67 576 251 58 176 441 564 569 194 24 669 73 262 457 259 619 78 400 579 222 626 269 47 80 315 160 194 455 186 315 424 197 246 683 220 68 682 83 233 290 664 273 598 362 305 674 614 321 575 362 120 14 534 62 436 294 351 485 396",
"output": "144"
},
{
"input": "100 290\n244 49 276 77 449 261 468 458 201 424 9 131 300 88 432 394 104 77 13 289 435 259 111 453 168 394 156 412 351 576 178 530 81 271 228 564 125 328 42 372 205 61 180 471 33 360 567 331 222 318 241 117 529 169 188 484 202 202 299 268 246 343 44 364 333 494 59 236 84 485 50 8 428 8 571 227 205 310 210 9 324 472 368 490 114 84 296 305 411 351 569 393 283 120 510 171 232 151 134 366",
"output": "145"
},
{
"input": "1 1\n1",
"output": "1"
},
{
"input": "1 1\n2",
"output": "2"
},
{
"input": "46 71\n30 26 56 138 123 77 60 122 73 45 79 10 130 3 14 1 38 46 128 50 82 16 32 68 28 98 62 106 2 49 131 11 114 39 139 70 40 50 45 137 33 30 35 136 135 19",
"output": "63"
},
{
"input": "20 723\n212 602 293 591 754 91 1135 640 80 495 845 928 1399 498 926 1431 1226 869 814 1386",
"output": "31"
},
{
"input": "48 864\n843 1020 751 1694 18 1429 1395 1174 272 1158 1628 1233 1710 441 765 561 778 748 1501 1200 563 1263 1398 1687 1518 1640 1591 839 500 466 1603 1587 1201 1209 432 868 1159 639 649 628 9 91 1036 147 896 1557 941 518",
"output": "75"
},
{
"input": "26 708\n549 241 821 734 945 1161 566 1268 216 30 1142 730 529 1014 255 168 796 1148 89 113 1328 286 743 871 1259 1397",
"output": "41"
},
{
"input": "75 940\n1620 1745 1599 441 64 1466 1496 1239 1716 1475 778 106 1136 1212 1261 444 781 257 1071 747 626 232 609 1544 682 1326 469 1361 1460 1450 1207 1319 922 625 1737 1057 1698 592 692 80 1016 541 1254 201 682 1007 847 206 1066 809 259 109 240 1611 219 1455 1326 1377 1827 786 42 1002 1382 1592 543 1866 1198 334 1524 1760 340 1566 955 257 1118",
"output": "116"
}
] | 1,692,358,021
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 29
| 31
| 0
|
n,h=map(int,input().split(" "))
m=list(map(int,input().split(" ")))
ans= n
for i in m:
if i>h:
ans+=1
print(ans)
|
Title: Vanya and Fence
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vanya and his friends are walking along the fence of height *h* and they do not want the guard to notice them. In order to achieve this the height of each of the friends should not exceed *h*. If the height of some person is greater than *h* he can bend down and then he surely won't be noticed by the guard. The height of the *i*-th person is equal to *a**i*.
Consider the width of the person walking as usual to be equal to 1, while the width of the bent person is equal to 2. Friends want to talk to each other while walking, so they would like to walk in a single row. What is the minimum width of the road, such that friends can walk in a row and remain unattended by the guard?
Input Specification:
The first line of the input contains two integers *n* and *h* (1<=≤<=*n*<=≤<=1000, 1<=≤<=*h*<=≤<=1000) — the number of friends and the height of the fence, respectively.
The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=2*h*), the *i*-th of them is equal to the height of the *i*-th person.
Output Specification:
Print a single integer — the minimum possible valid width of the road.
Demo Input:
['3 7\n4 5 14\n', '6 1\n1 1 1 1 1 1\n', '6 5\n7 6 8 9 10 5\n']
Demo Output:
['4\n', '6\n', '11\n']
Note:
In the first sample, only person number 3 must bend down, so the required width is equal to 1 + 1 + 2 = 4.
In the second sample, all friends are short enough and no one has to bend, so the width 1 + 1 + 1 + 1 + 1 + 1 = 6 is enough.
In the third sample, all the persons have to bend, except the last one. The required minimum width of the road is equal to 2 + 2 + 2 + 2 + 2 + 1 = 11.
|
```python
n,h=map(int,input().split(" "))
m=list(map(int,input().split(" ")))
ans= n
for i in m:
if i>h:
ans+=1
print(ans)
```
| 3
|
|
638
|
C
|
Road Improvement
|
PROGRAMMING
| 1,800
|
[
"*special",
"dfs and similar",
"graphs",
"greedy",
"trees"
] | null | null |
In Berland there are *n* cities and *n*<=-<=1 bidirectional roads. Each road connects some pair of cities, from any city you can get to any other one using only the given roads.
In each city there is exactly one repair brigade. To repair some road, you need two teams based in the cities connected by the road to work simultaneously for one day. Both brigades repair one road for the whole day and cannot take part in repairing other roads on that day. But the repair brigade can do nothing on that day.
Determine the minimum number of days needed to repair all the roads. The brigades cannot change the cities where they initially are.
|
The first line of the input contains a positive integer *n* (2<=≤<=*n*<=≤<=200<=000) — the number of cities in Berland.
Each of the next *n*<=-<=1 lines contains two numbers *u**i*, *v**i*, meaning that the *i*-th road connects city *u**i* and city *v**i* (1<=≤<=*u**i*,<=*v**i*<=≤<=*n*, *u**i*<=≠<=*v**i*).
|
First print number *k* — the minimum number of days needed to repair all the roads in Berland.
In next *k* lines print the description of the roads that should be repaired on each of the *k* days. On the *i*-th line print first number *d**i* — the number of roads that should be repaired on the *i*-th day, and then *d**i* space-separated integers — the numbers of the roads that should be repaired on the *i*-th day. The roads are numbered according to the order in the input, starting from one.
If there are multiple variants, you can print any of them.
|
[
"4\n1 2\n3 4\n3 2\n",
"6\n3 4\n5 4\n3 2\n1 3\n4 6\n"
] |
[
"2\n2 2 1\n1 3\n",
"3\n1 1 \n2 2 3 \n2 4 5 \n"
] |
In the first sample you can repair all the roads in two days, for example, if you repair roads 1 and 2 on the first day and road 3 — on the second day.
| 1,500
|
[
{
"input": "4\n1 2\n3 4\n3 2",
"output": "2\n2 1 2 \n1 3 "
},
{
"input": "6\n3 4\n5 4\n3 2\n1 3\n4 6",
"output": "3\n1 1 \n2 2 3 \n2 4 5 "
},
{
"input": "8\n1 3\n1 6\n3 4\n6 2\n5 6\n6 7\n7 8",
"output": "4\n3 2 3 7 \n2 1 4 \n1 5 \n1 6 "
},
{
"input": "5\n1 2\n1 3\n1 4\n1 5",
"output": "4\n1 1 \n1 2 \n1 3 \n1 4 "
},
{
"input": "2\n1 2",
"output": "1\n1 1 "
},
{
"input": "2\n2 1",
"output": "1\n1 1 "
},
{
"input": "3\n1 2\n3 2",
"output": "2\n1 1 \n1 2 "
},
{
"input": "3\n1 3\n2 3",
"output": "2\n1 1 \n1 2 "
},
{
"input": "4\n1 4\n1 2\n4 3",
"output": "2\n1 1 \n2 2 3 "
},
{
"input": "4\n1 2\n1 3\n1 4",
"output": "3\n1 1 \n1 2 \n1 3 "
},
{
"input": "6\n1 2\n1 3\n1 4\n3 5\n4 6",
"output": "3\n3 1 4 5 \n1 2 \n1 3 "
},
{
"input": "6\n1 2\n1 3\n1 4\n3 5\n3 6",
"output": "3\n2 1 4 \n1 2 \n2 3 5 "
},
{
"input": "8\n1 2\n2 3\n3 4\n1 5\n5 6\n6 7\n1 8",
"output": "3\n3 1 3 5 \n3 2 4 6 \n1 7 "
},
{
"input": "10\n4 1\n9 5\n6 8\n4 9\n3 10\n2 8\n9 3\n10 7\n8 7",
"output": "3\n4 1 3 7 8 \n3 2 5 6 \n2 4 9 "
},
{
"input": "10\n2 4\n6 10\n10 3\n7 4\n7 9\n8 2\n3 1\n4 5\n2 6",
"output": "3\n4 1 2 5 7 \n3 3 4 6 \n2 8 9 "
},
{
"input": "2\n2 1",
"output": "1\n1 1 "
},
{
"input": "3\n3 2\n1 2",
"output": "2\n1 1 \n1 2 "
},
{
"input": "3\n3 1\n1 2",
"output": "2\n1 1 \n1 2 "
},
{
"input": "3\n2 1\n3 2",
"output": "2\n1 1 \n1 2 "
},
{
"input": "3\n1 2\n1 3",
"output": "2\n1 1 \n1 2 "
},
{
"input": "4\n1 2\n4 2\n3 4",
"output": "2\n2 1 3 \n1 2 "
},
{
"input": "4\n3 1\n1 4\n2 1",
"output": "3\n1 1 \n1 2 \n1 3 "
},
{
"input": "4\n1 3\n4 3\n2 4",
"output": "2\n2 1 3 \n1 2 "
},
{
"input": "4\n3 1\n1 2\n1 4",
"output": "3\n1 1 \n1 2 \n1 3 "
},
{
"input": "4\n3 4\n1 4\n3 2",
"output": "2\n1 1 \n2 2 3 "
},
{
"input": "4\n1 2\n1 3\n4 1",
"output": "3\n1 1 \n1 2 \n1 3 "
},
{
"input": "10\n2 8\n5 10\n3 4\n1 6\n3 9\n1 7\n4 8\n10 8\n1 8",
"output": "4\n4 1 2 3 4 \n3 5 6 7 \n1 8 \n1 9 "
},
{
"input": "12\n1 2\n2 3\n2 4\n2 5\n5 7\n5 6\n5 8\n5 12\n12 10\n12 11\n12 9",
"output": "5\n2 4 9 \n3 1 5 10 \n3 2 6 11 \n2 3 7 \n1 8 "
}
] | 1,458,498,434
| 23,234
|
Python 3
|
WRONG_ANSWER
|
PRETESTS
| 2
| 77
| 5,427,200
|
import copy
def Core(data):
back_data = copy.copy(data)
count = 0
result = []
while len(data):
count += 1
items = [data[0]]
del data[0]
key = True
delList = []
for i in range(len(data)):
el1 = data[i]
for el2 in items:
for el3 in el1:
if el3 == el2[0] or el3 == el2[1]:
key = False
if key:
items.append(el1)
delList.append(i)
for i in delList:
del data[i]
items = [{"num":back_data.index(el)+1, "data":el} for el in items]
result.append(items)
print (count)
for el in result:
res = str(len(el))
for el1 in el:
res += " {}".format(el1["num"])
print (res)
Core([[int(num) for num in input().split(" ")] for i in range(int(input())-1)])
|
Title: Road Improvement
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
In Berland there are *n* cities and *n*<=-<=1 bidirectional roads. Each road connects some pair of cities, from any city you can get to any other one using only the given roads.
In each city there is exactly one repair brigade. To repair some road, you need two teams based in the cities connected by the road to work simultaneously for one day. Both brigades repair one road for the whole day and cannot take part in repairing other roads on that day. But the repair brigade can do nothing on that day.
Determine the minimum number of days needed to repair all the roads. The brigades cannot change the cities where they initially are.
Input Specification:
The first line of the input contains a positive integer *n* (2<=≤<=*n*<=≤<=200<=000) — the number of cities in Berland.
Each of the next *n*<=-<=1 lines contains two numbers *u**i*, *v**i*, meaning that the *i*-th road connects city *u**i* and city *v**i* (1<=≤<=*u**i*,<=*v**i*<=≤<=*n*, *u**i*<=≠<=*v**i*).
Output Specification:
First print number *k* — the minimum number of days needed to repair all the roads in Berland.
In next *k* lines print the description of the roads that should be repaired on each of the *k* days. On the *i*-th line print first number *d**i* — the number of roads that should be repaired on the *i*-th day, and then *d**i* space-separated integers — the numbers of the roads that should be repaired on the *i*-th day. The roads are numbered according to the order in the input, starting from one.
If there are multiple variants, you can print any of them.
Demo Input:
['4\n1 2\n3 4\n3 2\n', '6\n3 4\n5 4\n3 2\n1 3\n4 6\n']
Demo Output:
['2\n2 2 1\n1 3\n', '3\n1 1 \n2 2 3 \n2 4 5 \n']
Note:
In the first sample you can repair all the roads in two days, for example, if you repair roads 1 and 2 on the first day and road 3 — on the second day.
|
```python
import copy
def Core(data):
back_data = copy.copy(data)
count = 0
result = []
while len(data):
count += 1
items = [data[0]]
del data[0]
key = True
delList = []
for i in range(len(data)):
el1 = data[i]
for el2 in items:
for el3 in el1:
if el3 == el2[0] or el3 == el2[1]:
key = False
if key:
items.append(el1)
delList.append(i)
for i in delList:
del data[i]
items = [{"num":back_data.index(el)+1, "data":el} for el in items]
result.append(items)
print (count)
for el in result:
res = str(len(el))
for el1 in el:
res += " {}".format(el1["num"])
print (res)
Core([[int(num) for num in input().split(" ")] for i in range(int(input())-1)])
```
| 0
|
|
717
|
C
|
Potions Homework
|
PROGRAMMING
| 1,200
|
[
"implementation",
"sortings"
] | null | null |
Harry Water, Ronaldo, Her-my-oh-knee and their friends have started a new school year at their MDCS School of Speechcraft and Misery. At the time, they are very happy to have seen each other after a long time. The sun is shining, birds are singing, flowers are blooming, and their Potions class teacher, professor Snipe is sulky as usual. Due to his angst fueled by disappointment in his own life, he has given them a lot of homework in Potions class.
Each of the *n* students has been assigned a single task. Some students do certain tasks faster than others. Thus, they want to redistribute the tasks so that each student still does exactly one task, and that all tasks are finished. Each student has their own laziness level, and each task has its own difficulty level. Professor Snipe is trying hard to improve their work ethics, so each student’s laziness level is equal to their task’s difficulty level. Both sets of values are given by the sequence *a*, where *a**i* represents both the laziness level of the *i*-th student and the difficulty of his task.
The time a student needs to finish a task is equal to the product of their laziness level and the task’s difficulty. They are wondering, what is the minimum possible total time they must spend to finish all tasks if they distribute them in the optimal way. Each person should receive one task and each task should be given to one person. Print the answer modulo 10<=007.
|
The first line of input contains integer *n* (1<=≤<=*n*<=≤<=100<=000) — the number of tasks. The next *n* lines contain exactly one integer number *a**i* (1<=≤<=*a**i*<=≤<=100<=000) — both the difficulty of the initial task and the laziness of the *i*-th students.
|
Print the minimum total time to finish all tasks modulo 10<=007.
|
[
"2\n1\n3\n"
] |
[
"6\n"
] |
In the first sample, if the students switch their tasks, they will be able to finish them in 3 + 3 = 6 time units.
| 0
|
[
{
"input": "2\n1\n3",
"output": "6"
}
] | 1,563,538,799
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 1
| 249
| 3,584,000
|
t = int(input())
c = []
for _ in range(t):
p = int(input())
c.append(p)
c = sorted(c)
l = 0
for i in range(len(c)//2):
l+=c[i]*c[t-i-1]
print(l*2)
|
Title: Potions Homework
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Harry Water, Ronaldo, Her-my-oh-knee and their friends have started a new school year at their MDCS School of Speechcraft and Misery. At the time, they are very happy to have seen each other after a long time. The sun is shining, birds are singing, flowers are blooming, and their Potions class teacher, professor Snipe is sulky as usual. Due to his angst fueled by disappointment in his own life, he has given them a lot of homework in Potions class.
Each of the *n* students has been assigned a single task. Some students do certain tasks faster than others. Thus, they want to redistribute the tasks so that each student still does exactly one task, and that all tasks are finished. Each student has their own laziness level, and each task has its own difficulty level. Professor Snipe is trying hard to improve their work ethics, so each student’s laziness level is equal to their task’s difficulty level. Both sets of values are given by the sequence *a*, where *a**i* represents both the laziness level of the *i*-th student and the difficulty of his task.
The time a student needs to finish a task is equal to the product of their laziness level and the task’s difficulty. They are wondering, what is the minimum possible total time they must spend to finish all tasks if they distribute them in the optimal way. Each person should receive one task and each task should be given to one person. Print the answer modulo 10<=007.
Input Specification:
The first line of input contains integer *n* (1<=≤<=*n*<=≤<=100<=000) — the number of tasks. The next *n* lines contain exactly one integer number *a**i* (1<=≤<=*a**i*<=≤<=100<=000) — both the difficulty of the initial task and the laziness of the *i*-th students.
Output Specification:
Print the minimum total time to finish all tasks modulo 10<=007.
Demo Input:
['2\n1\n3\n']
Demo Output:
['6\n']
Note:
In the first sample, if the students switch their tasks, they will be able to finish them in 3 + 3 = 6 time units.
|
```python
t = int(input())
c = []
for _ in range(t):
p = int(input())
c.append(p)
c = sorted(c)
l = 0
for i in range(len(c)//2):
l+=c[i]*c[t-i-1]
print(l*2)
```
| 0
|
|
102
|
B
|
Sum of Digits
|
PROGRAMMING
| 1,000
|
[
"implementation"
] |
B. Sum of Digits
|
2
|
265
|
Having watched the last Harry Potter film, little Gerald also decided to practice magic. He found in his father's magical book a spell that turns any number in the sum of its digits. At the moment Gerald learned that, he came across a number *n*. How many times can Gerald put a spell on it until the number becomes one-digit?
|
The first line contains the only integer *n* (0<=≤<=*n*<=≤<=10100000). It is guaranteed that *n* doesn't contain any leading zeroes.
|
Print the number of times a number can be replaced by the sum of its digits until it only contains one digit.
|
[
"0\n",
"10\n",
"991\n"
] |
[
"0\n",
"1\n",
"3\n"
] |
In the first sample the number already is one-digit — Herald can't cast a spell.
The second test contains number 10. After one casting of a spell it becomes 1, and here the process is completed. Thus, Gerald can only cast the spell once.
The third test contains number 991. As one casts a spell the following transformations take place: 991 → 19 → 10 → 1. After three transformations the number becomes one-digit.
| 1,000
|
[
{
"input": "0",
"output": "0"
},
{
"input": "10",
"output": "1"
},
{
"input": "991",
"output": "3"
},
{
"input": "99",
"output": "2"
},
{
"input": "100",
"output": "1"
},
{
"input": "123456789",
"output": "2"
},
{
"input": "32",
"output": "1"
},
{
"input": "86",
"output": "2"
},
{
"input": "2",
"output": "0"
},
{
"input": "8",
"output": "0"
},
{
"input": "34",
"output": "1"
},
{
"input": "13",
"output": "1"
},
{
"input": "28",
"output": "2"
},
{
"input": "23",
"output": "1"
},
{
"input": "57",
"output": "2"
},
{
"input": "29",
"output": "2"
},
{
"input": "353869285",
"output": "3"
},
{
"input": "549548646",
"output": "2"
},
{
"input": "858893424",
"output": "2"
},
{
"input": "644818852",
"output": "3"
},
{
"input": "360322525",
"output": "3"
},
{
"input": "122937520",
"output": "2"
},
{
"input": "288403032",
"output": "2"
},
{
"input": "677257481",
"output": "3"
},
{
"input": "58059561",
"output": "3"
},
{
"input": "211288847",
"output": "2"
},
{
"input": "339900034079539584",
"output": "2"
},
{
"input": "784084029310269952",
"output": "3"
},
{
"input": "774730557264864000",
"output": "3"
},
{
"input": "478233807148352256",
"output": "3"
},
{
"input": "165646874056812544",
"output": "3"
},
{
"input": "477533739511673792",
"output": "3"
},
{
"input": "660119944377002240",
"output": "3"
},
{
"input": "448375218506078080",
"output": "3"
},
{
"input": "77213334785795616",
"output": "3"
},
{
"input": "165767221702271872",
"output": "3"
},
{
"input": "1",
"output": "0"
},
{
"input": "5",
"output": "0"
},
{
"input": "8",
"output": "0"
},
{
"input": "156161456146164104103460452045416165146141414651641564105461465156445621465146514562146145465165145145614561465145614561",
"output": "3"
},
{
"input": "9",
"output": "0"
}
] | 1,674,182,676
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 51
| 122
| 0
|
# LUOGU_RID: 100284783
t = input().strip()
def f(x):
if len(x) > 1:
s = 0
for i in x: s += int(i)
return f(str(s)) + 1
return 0
print(f(t))
|
Title: Sum of Digits
Time Limit: 2 seconds
Memory Limit: 265 megabytes
Problem Description:
Having watched the last Harry Potter film, little Gerald also decided to practice magic. He found in his father's magical book a spell that turns any number in the sum of its digits. At the moment Gerald learned that, he came across a number *n*. How many times can Gerald put a spell on it until the number becomes one-digit?
Input Specification:
The first line contains the only integer *n* (0<=≤<=*n*<=≤<=10100000). It is guaranteed that *n* doesn't contain any leading zeroes.
Output Specification:
Print the number of times a number can be replaced by the sum of its digits until it only contains one digit.
Demo Input:
['0\n', '10\n', '991\n']
Demo Output:
['0\n', '1\n', '3\n']
Note:
In the first sample the number already is one-digit — Herald can't cast a spell.
The second test contains number 10. After one casting of a spell it becomes 1, and here the process is completed. Thus, Gerald can only cast the spell once.
The third test contains number 991. As one casts a spell the following transformations take place: 991 → 19 → 10 → 1. After three transformations the number becomes one-digit.
|
```python
# LUOGU_RID: 100284783
t = input().strip()
def f(x):
if len(x) > 1:
s = 0
for i in x: s += int(i)
return f(str(s)) + 1
return 0
print(f(t))
```
| 3.9695
|
265
|
A
|
Colorful Stones (Simplified Edition)
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
There is a sequence of colorful stones. The color of each stone is one of red, green, or blue. You are given a string *s*. The *i*-th (1-based) character of *s* represents the color of the *i*-th stone. If the character is "R", "G", or "B", the color of the corresponding stone is red, green, or blue, respectively.
Initially Squirrel Liss is standing on the first stone. You perform instructions one or more times.
Each instruction is one of the three types: "RED", "GREEN", or "BLUE". After an instruction *c*, if Liss is standing on a stone whose colors is *c*, Liss will move one stone forward, else she will not move.
You are given a string *t*. The number of instructions is equal to the length of *t*, and the *i*-th character of *t* represents the *i*-th instruction.
Calculate the final position of Liss (the number of the stone she is going to stand on in the end) after performing all the instructions, and print its 1-based position. It is guaranteed that Liss don't move out of the sequence.
|
The input contains two lines. The first line contains the string *s* (1<=≤<=|*s*|<=≤<=50). The second line contains the string *t* (1<=≤<=|*t*|<=≤<=50). The characters of each string will be one of "R", "G", or "B". It is guaranteed that Liss don't move out of the sequence.
|
Print the final 1-based position of Liss in a single line.
|
[
"RGB\nRRR\n",
"RRRBGBRBBB\nBBBRR\n",
"BRRBGBRGRBGRGRRGGBGBGBRGBRGRGGGRBRRRBRBBBGRRRGGBBB\nBBRBGGRGRGBBBRBGRBRBBBBRBRRRBGBBGBBRRBBGGRBRRBRGRB\n"
] |
[
"2\n",
"3\n",
"15\n"
] |
none
| 500
|
[
{
"input": "RGB\nRRR",
"output": "2"
},
{
"input": "RRRBGBRBBB\nBBBRR",
"output": "3"
},
{
"input": "BRRBGBRGRBGRGRRGGBGBGBRGBRGRGGGRBRRRBRBBBGRRRGGBBB\nBBRBGGRGRGBBBRBGRBRBBBBRBRRRBGBBGBBRRBBGGRBRRBRGRB",
"output": "15"
},
{
"input": "G\nRRBBRBRRBR",
"output": "1"
},
{
"input": "RRRRRBRRBRRGRBGGRRRGRBBRBBBBBRGRBGBRRGBBBRBBGBRGBB\nB",
"output": "1"
},
{
"input": "RRGGBRGRBG\nBRRGGBBGGR",
"output": "7"
},
{
"input": "BBRRGBGGRGBRGBRBRBGR\nGGGRBGGGBRRRRGRBGBGRGRRBGRBGBG",
"output": "15"
},
{
"input": "GBRRBGBGBBBBRRRGBGRRRGBGBBBRGR\nRRGBRRGRBBBBBBGRRBBR",
"output": "8"
},
{
"input": "BRGRRGRGRRGBBGBBBRRBBRRBGBBGRGBBGGRGBRBGGGRRRBGGBB\nRGBBGRRBBBRRGRRBRBBRGBBGGGRGBGRRRRBRBGGBRBGGGRGBRR",
"output": "16"
},
{
"input": "GGRGGBRRGRGBRRGGRBBGGRRGBBBGBBBGGRBGGBRBBRGBRRRBRG\nGGRGRRRRRRRRRGBBBBRGBRGRGRRGBBRGGBRBBRBGBRGRRRRGGR",
"output": "18"
},
{
"input": "RBBRBGBBGGGBRRBGBRGRRGGRBBBBGRBGGBRRBGBBRBRGBBGGGG\nBRRGRBGRBGBRGBRBGGBBBGBBRGRBGRGRBGRBGGRRBGBRGRRBBG",
"output": "23"
},
{
"input": "RRGGRRBRGRGBRGBRGBBRGGGBRBGBRGBRGGBRBRGBGRRBBGGRBR\nBRGRBBBGRBGRRGGRRRRRRRRGGGGGGGGBGGGGGGGRGRBBRGRGBR",
"output": "14"
},
{
"input": "RBRBRRRRRGGR\nBBBBRRGGBGRBRGBBRGGGRGGBRRBRBRBGGG",
"output": "12"
},
{
"input": "GGRGGGBRGRGRBBRGGGRBGRRR\nGBBBBGBGBGBBBRGGRGGBGRRGRRRGBGB",
"output": "12"
},
{
"input": "RGRBGBRBBGBRRGGGBBGBRRBGRGBBBBBGRRRGGRBB\nBGR",
"output": "2"
},
{
"input": "R\nB",
"output": "1"
},
{
"input": "RRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRR\nRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRR",
"output": "50"
},
{
"input": "RRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRR\nGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGG",
"output": "1"
},
{
"input": "R\nGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGG",
"output": "1"
}
] | 1,588,083,779
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 0
| 216
| 0
|
s = input()
t = input()
c=1
i=0
j=0
while i<len(s) and j<len(t):
if s[i] == t[j]:
c+=1
i+=1
j+=1
print(c+1)
|
Title: Colorful Stones (Simplified Edition)
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There is a sequence of colorful stones. The color of each stone is one of red, green, or blue. You are given a string *s*. The *i*-th (1-based) character of *s* represents the color of the *i*-th stone. If the character is "R", "G", or "B", the color of the corresponding stone is red, green, or blue, respectively.
Initially Squirrel Liss is standing on the first stone. You perform instructions one or more times.
Each instruction is one of the three types: "RED", "GREEN", or "BLUE". After an instruction *c*, if Liss is standing on a stone whose colors is *c*, Liss will move one stone forward, else she will not move.
You are given a string *t*. The number of instructions is equal to the length of *t*, and the *i*-th character of *t* represents the *i*-th instruction.
Calculate the final position of Liss (the number of the stone she is going to stand on in the end) after performing all the instructions, and print its 1-based position. It is guaranteed that Liss don't move out of the sequence.
Input Specification:
The input contains two lines. The first line contains the string *s* (1<=≤<=|*s*|<=≤<=50). The second line contains the string *t* (1<=≤<=|*t*|<=≤<=50). The characters of each string will be one of "R", "G", or "B". It is guaranteed that Liss don't move out of the sequence.
Output Specification:
Print the final 1-based position of Liss in a single line.
Demo Input:
['RGB\nRRR\n', 'RRRBGBRBBB\nBBBRR\n', 'BRRBGBRGRBGRGRRGGBGBGBRGBRGRGGGRBRRRBRBBBGRRRGGBBB\nBBRBGGRGRGBBBRBGRBRBBBBRBRRRBGBBGBBRRBBGGRBRRBRGRB\n']
Demo Output:
['2\n', '3\n', '15\n']
Note:
none
|
```python
s = input()
t = input()
c=1
i=0
j=0
while i<len(s) and j<len(t):
if s[i] == t[j]:
c+=1
i+=1
j+=1
print(c+1)
```
| 0
|
|
452
|
C
|
Magic Trick
|
PROGRAMMING
| 2,100
|
[
"combinatorics",
"math",
"probabilities"
] | null | null |
Alex enjoys performing magic tricks. He has a trick that requires a deck of *n* cards. He has *m* identical decks of *n* different cards each, which have been mixed together. When Alex wishes to perform the trick, he grabs *n* cards at random and performs the trick with those. The resulting deck looks like a normal deck, but may have duplicates of some cards.
The trick itself is performed as follows: first Alex allows you to choose a random card from the deck. You memorize the card and put it back in the deck. Then Alex shuffles the deck, and pulls out a card. If the card matches the one you memorized, the trick is successful.
You don't think Alex is a very good magician, and that he just pulls a card randomly from the deck. Determine the probability of the trick being successful if this is the case.
|
First line of the input consists of two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=1000), separated by space — number of cards in each deck, and number of decks.
|
On the only line of the output print one floating point number – probability of Alex successfully performing the trick. Relative or absolute error of your answer should not be higher than 10<=-<=6.
|
[
"2 2\n",
"4 4\n",
"1 2\n"
] |
[
"0.6666666666666666\n",
"0.4000000000000000\n",
"1.0000000000000000\n"
] |
In the first sample, with probability <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/64c94d13eeb330b494061e86538db66574ad0f7d.png" style="max-width: 100.0%;max-height: 100.0%;"/> Alex will perform the trick with two cards with the same value from two different decks. In this case the trick is guaranteed to succeed.
With the remaining <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/14b21b617fcd2e25700376368355f7bbf975d8de.png" style="max-width: 100.0%;max-height: 100.0%;"/> probability he took two different cards, and the probability of pulling off the trick is <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/eb946338365d9781f7d2e9ec692c26702d0ae3a7.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
The resulting probability is <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/f54a03c9fa9df64ba08161730756d50b780a5f43.png" style="max-width: 100.0%;max-height: 100.0%;"/>
| 1,000
|
[
{
"input": "2 2",
"output": "0.6666666666666666"
},
{
"input": "4 4",
"output": "0.4000000000000000"
},
{
"input": "1 2",
"output": "1.0000000000000000"
},
{
"input": "2 1",
"output": "0.5000000000000000"
},
{
"input": "10 10",
"output": "0.1818181818181818"
},
{
"input": "1000 1000",
"output": "0.0019980019980020"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "987 123",
"output": "0.0020170953866492"
},
{
"input": "999 999",
"output": "0.0020000000000000"
},
{
"input": "1 999",
"output": "1.0000000000000000"
},
{
"input": "998 1",
"output": "0.0010020040080160"
},
{
"input": "2 987",
"output": "0.7498732894069944"
},
{
"input": "555 543",
"output": "0.0035970508143694"
},
{
"input": "321 123",
"output": "0.0061956542837219"
},
{
"input": "2 3",
"output": "0.7000000000000000"
},
{
"input": "461 1000",
"output": "0.0043315295751250"
},
{
"input": "678 231",
"output": "0.0029413109179425"
}
] | 1,477,081,754
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 62
| 0
|
S=str(input())
l=list(map(int, S.split(' ')))
n,m=l[0],l[1]
S=0
t=1/m
l=m*n-m-n
x=max(n,m)
y=min(n,m)
for i in range(1,y+1):
if i>1:
t=t*i*(n+1-i)*(n+1-i)/((i-1)*(i-1)*(l+i)*(n*m-i+1))
S=S/(n*m-i+1)+t
for i in range(x*y-x-y+2,x*y-x+1):
S=S*i
print(S)
|
Title: Magic Trick
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Alex enjoys performing magic tricks. He has a trick that requires a deck of *n* cards. He has *m* identical decks of *n* different cards each, which have been mixed together. When Alex wishes to perform the trick, he grabs *n* cards at random and performs the trick with those. The resulting deck looks like a normal deck, but may have duplicates of some cards.
The trick itself is performed as follows: first Alex allows you to choose a random card from the deck. You memorize the card and put it back in the deck. Then Alex shuffles the deck, and pulls out a card. If the card matches the one you memorized, the trick is successful.
You don't think Alex is a very good magician, and that he just pulls a card randomly from the deck. Determine the probability of the trick being successful if this is the case.
Input Specification:
First line of the input consists of two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=1000), separated by space — number of cards in each deck, and number of decks.
Output Specification:
On the only line of the output print one floating point number – probability of Alex successfully performing the trick. Relative or absolute error of your answer should not be higher than 10<=-<=6.
Demo Input:
['2 2\n', '4 4\n', '1 2\n']
Demo Output:
['0.6666666666666666\n', '0.4000000000000000\n', '1.0000000000000000\n']
Note:
In the first sample, with probability <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/64c94d13eeb330b494061e86538db66574ad0f7d.png" style="max-width: 100.0%;max-height: 100.0%;"/> Alex will perform the trick with two cards with the same value from two different decks. In this case the trick is guaranteed to succeed.
With the remaining <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/14b21b617fcd2e25700376368355f7bbf975d8de.png" style="max-width: 100.0%;max-height: 100.0%;"/> probability he took two different cards, and the probability of pulling off the trick is <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/eb946338365d9781f7d2e9ec692c26702d0ae3a7.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
The resulting probability is <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/f54a03c9fa9df64ba08161730756d50b780a5f43.png" style="max-width: 100.0%;max-height: 100.0%;"/>
|
```python
S=str(input())
l=list(map(int, S.split(' ')))
n,m=l[0],l[1]
S=0
t=1/m
l=m*n-m-n
x=max(n,m)
y=min(n,m)
for i in range(1,y+1):
if i>1:
t=t*i*(n+1-i)*(n+1-i)/((i-1)*(i-1)*(l+i)*(n*m-i+1))
S=S/(n*m-i+1)+t
for i in range(x*y-x-y+2,x*y-x+1):
S=S*i
print(S)
```
| 0
|
|
614
|
A
|
Link/Cut Tree
|
PROGRAMMING
| 1,500
|
[
"brute force",
"implementation"
] | null | null |
Programmer Rostislav got seriously interested in the Link/Cut Tree data structure, which is based on Splay trees. Specifically, he is now studying the *expose* procedure.
Unfortunately, Rostislav is unable to understand the definition of this procedure, so he decided to ask programmer Serezha to help him. Serezha agreed to help if Rostislav solves a simple task (and if he doesn't, then why would he need Splay trees anyway?)
Given integers *l*, *r* and *k*, you need to print all powers of number *k* within range from *l* to *r* inclusive. However, Rostislav doesn't want to spent time doing this, as he got interested in playing a network game called Agar with Gleb. Help him!
|
The first line of the input contains three space-separated integers *l*, *r* and *k* (1<=≤<=*l*<=≤<=*r*<=≤<=1018, 2<=≤<=*k*<=≤<=109).
|
Print all powers of number *k*, that lie within range from *l* to *r* in the increasing order. If there are no such numbers, print "-1" (without the quotes).
|
[
"1 10 2\n",
"2 4 5\n"
] |
[
"1 2 4 8 ",
"-1"
] |
Note to the first sample: numbers 2<sup class="upper-index">0</sup> = 1, 2<sup class="upper-index">1</sup> = 2, 2<sup class="upper-index">2</sup> = 4, 2<sup class="upper-index">3</sup> = 8 lie within the specified range. The number 2<sup class="upper-index">4</sup> = 16 is greater then 10, thus it shouldn't be printed.
| 500
|
[
{
"input": "1 10 2",
"output": "1 2 4 8 "
},
{
"input": "2 4 5",
"output": "-1"
},
{
"input": "18102 43332383920 28554",
"output": "28554 815330916 "
},
{
"input": "19562 31702689720 17701",
"output": "313325401 "
},
{
"input": "11729 55221128400 313",
"output": "97969 30664297 9597924961 "
},
{
"input": "5482 100347128000 342",
"output": "116964 40001688 13680577296 "
},
{
"input": "3680 37745933600 10",
"output": "10000 100000 1000000 10000000 100000000 1000000000 10000000000 "
},
{
"input": "17098 191120104800 43",
"output": "79507 3418801 147008443 6321363049 "
},
{
"input": "10462 418807699200 2",
"output": "16384 32768 65536 131072 262144 524288 1048576 2097152 4194304 8388608 16777216 33554432 67108864 134217728 268435456 536870912 1073741824 2147483648 4294967296 8589934592 17179869184 34359738368 68719476736 137438953472 274877906944 "
},
{
"input": "30061 641846400000 3",
"output": "59049 177147 531441 1594323 4782969 14348907 43046721 129140163 387420489 1162261467 3486784401 10460353203 31381059609 94143178827 282429536481 "
},
{
"input": "1 1000000000000000000 2",
"output": "1 2 4 8 16 32 64 128 256 512 1024 2048 4096 8192 16384 32768 65536 131072 262144 524288 1048576 2097152 4194304 8388608 16777216 33554432 67108864 134217728 268435456 536870912 1073741824 2147483648 4294967296 8589934592 17179869184 34359738368 68719476736 137438953472 274877906944 549755813888 1099511627776 2199023255552 4398046511104 8796093022208 17592186044416 35184372088832 70368744177664 140737488355328 281474976710656 562949953421312 1125899906842624 2251799813685248 4503599627370496 900719925474099..."
},
{
"input": "32 2498039712000 4",
"output": "64 256 1024 4096 16384 65536 262144 1048576 4194304 16777216 67108864 268435456 1073741824 4294967296 17179869184 68719476736 274877906944 1099511627776 "
},
{
"input": "1 2576683920000 2",
"output": "1 2 4 8 16 32 64 128 256 512 1024 2048 4096 8192 16384 32768 65536 131072 262144 524288 1048576 2097152 4194304 8388608 16777216 33554432 67108864 134217728 268435456 536870912 1073741824 2147483648 4294967296 8589934592 17179869184 34359738368 68719476736 137438953472 274877906944 549755813888 1099511627776 2199023255552 "
},
{
"input": "5 25 5",
"output": "5 25 "
},
{
"input": "1 90 90",
"output": "1 90 "
},
{
"input": "95 2200128528000 68",
"output": "4624 314432 21381376 1453933568 98867482624 "
},
{
"input": "64 426314644000 53",
"output": "2809 148877 7890481 418195493 22164361129 "
},
{
"input": "198765 198765 198765",
"output": "198765 "
},
{
"input": "42 2845016496000 12",
"output": "144 1728 20736 248832 2985984 35831808 429981696 5159780352 61917364224 743008370688 "
},
{
"input": "6 6 3",
"output": "-1"
},
{
"input": "1 10 11",
"output": "1 "
},
{
"input": "2 10 11",
"output": "-1"
},
{
"input": "87 160 41",
"output": "-1"
},
{
"input": "237171123124584251 923523399718980912 7150",
"output": "-1"
},
{
"input": "101021572000739548 453766043506276015 8898",
"output": "-1"
},
{
"input": "366070689449360724 928290634811046396 8230",
"output": "-1"
},
{
"input": "438133886369772308 942612870269666780 7193",
"output": "-1"
},
{
"input": "10 10 10",
"output": "10 "
},
{
"input": "16 16 256",
"output": "-1"
},
{
"input": "1 1000000000000000000 1000000000",
"output": "1 1000000000 1000000000000000000 "
},
{
"input": "1000000000000000000 1000000000000000000 1000000000",
"output": "1000000000000000000 "
},
{
"input": "1000000000 1000000000000000000 1000000000",
"output": "1000000000 1000000000000000000 "
},
{
"input": "1 1 4",
"output": "1 "
},
{
"input": "1 999999999999999999 1000000000",
"output": "1 1000000000 "
},
{
"input": "1 1000000000000000000 999999990",
"output": "1 999999990 999999980000000100 "
},
{
"input": "1 1000000000000000000 999999984",
"output": "1 999999984 999999968000000256 "
},
{
"input": "1 1000000000000000000 324325",
"output": "1 324325 105186705625 34114678301828125 "
},
{
"input": "1 1000000000000000000 999999523",
"output": "1 999999523 999999046000227529 "
},
{
"input": "1 243 3",
"output": "1 3 9 27 81 243 "
},
{
"input": "62769392426654367 567152589733560993 688813",
"output": "326816522793383797 "
},
{
"input": "1 1000000000000000000 690852001",
"output": "1 690852001 477276487285704001 "
},
{
"input": "1 1000000000000000000 918745157",
"output": "1 918745157 844092663510954649 "
},
{
"input": "1 1000000000000000000 131299843",
"output": "1 131299843 17239648771824649 "
},
{
"input": "2861381721051425 2861381721051425 1234",
"output": "-1"
}
] | 1,549,184,136
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 44
| 139
| 0
|
l , r , k = map(int , input().split())
K = k
k = 1
cnt = 0
while k <= r:
if k >= l:
print(k , end = ' ')
cnt+=1
k *= K
if cnt == 0:
print(-1)
|
Title: Link/Cut Tree
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Programmer Rostislav got seriously interested in the Link/Cut Tree data structure, which is based on Splay trees. Specifically, he is now studying the *expose* procedure.
Unfortunately, Rostislav is unable to understand the definition of this procedure, so he decided to ask programmer Serezha to help him. Serezha agreed to help if Rostislav solves a simple task (and if he doesn't, then why would he need Splay trees anyway?)
Given integers *l*, *r* and *k*, you need to print all powers of number *k* within range from *l* to *r* inclusive. However, Rostislav doesn't want to spent time doing this, as he got interested in playing a network game called Agar with Gleb. Help him!
Input Specification:
The first line of the input contains three space-separated integers *l*, *r* and *k* (1<=≤<=*l*<=≤<=*r*<=≤<=1018, 2<=≤<=*k*<=≤<=109).
Output Specification:
Print all powers of number *k*, that lie within range from *l* to *r* in the increasing order. If there are no such numbers, print "-1" (without the quotes).
Demo Input:
['1 10 2\n', '2 4 5\n']
Demo Output:
['1 2 4 8 ', '-1']
Note:
Note to the first sample: numbers 2<sup class="upper-index">0</sup> = 1, 2<sup class="upper-index">1</sup> = 2, 2<sup class="upper-index">2</sup> = 4, 2<sup class="upper-index">3</sup> = 8 lie within the specified range. The number 2<sup class="upper-index">4</sup> = 16 is greater then 10, thus it shouldn't be printed.
|
```python
l , r , k = map(int , input().split())
K = k
k = 1
cnt = 0
while k <= r:
if k >= l:
print(k , end = ' ')
cnt+=1
k *= K
if cnt == 0:
print(-1)
```
| 3
|
|
777
|
A
|
Shell Game
|
PROGRAMMING
| 1,000
|
[
"constructive algorithms",
"implementation",
"math"
] | null | null |
Bomboslav likes to look out of the window in his room and watch lads outside playing famous shell game. The game is played by two persons: operator and player. Operator takes three similar opaque shells and places a ball beneath one of them. Then he shuffles the shells by swapping some pairs and the player has to guess the current position of the ball.
Bomboslav noticed that guys are not very inventive, so the operator always swaps the left shell with the middle one during odd moves (first, third, fifth, etc.) and always swaps the middle shell with the right one during even moves (second, fourth, etc.).
Let's number shells from 0 to 2 from left to right. Thus the left shell is assigned number 0, the middle shell is 1 and the right shell is 2. Bomboslav has missed the moment when the ball was placed beneath the shell, but he knows that exactly *n* movements were made by the operator and the ball was under shell *x* at the end. Now he wonders, what was the initial position of the ball?
|
The first line of the input contains an integer *n* (1<=≤<=*n*<=≤<=2·109) — the number of movements made by the operator.
The second line contains a single integer *x* (0<=≤<=*x*<=≤<=2) — the index of the shell where the ball was found after *n* movements.
|
Print one integer from 0 to 2 — the index of the shell where the ball was initially placed.
|
[
"4\n2\n",
"1\n1\n"
] |
[
"1\n",
"0\n"
] |
In the first sample, the ball was initially placed beneath the middle shell and the operator completed four movements.
1. During the first move operator swapped the left shell and the middle shell. The ball is now under the left shell. 1. During the second move operator swapped the middle shell and the right one. The ball is still under the left shell. 1. During the third move operator swapped the left shell and the middle shell again. The ball is again in the middle. 1. Finally, the operators swapped the middle shell and the right shell. The ball is now beneath the right shell.
| 500
|
[
{
"input": "4\n2",
"output": "1"
},
{
"input": "1\n1",
"output": "0"
},
{
"input": "2\n2",
"output": "0"
},
{
"input": "3\n1",
"output": "1"
},
{
"input": "3\n2",
"output": "0"
},
{
"input": "3\n0",
"output": "2"
},
{
"input": "2000000000\n0",
"output": "1"
},
{
"input": "2\n0",
"output": "1"
},
{
"input": "2\n1",
"output": "2"
},
{
"input": "4\n0",
"output": "2"
},
{
"input": "4\n1",
"output": "0"
},
{
"input": "5\n0",
"output": "0"
},
{
"input": "5\n1",
"output": "2"
},
{
"input": "5\n2",
"output": "1"
},
{
"input": "6\n0",
"output": "0"
},
{
"input": "6\n1",
"output": "1"
},
{
"input": "6\n2",
"output": "2"
},
{
"input": "7\n0",
"output": "1"
},
{
"input": "7\n1",
"output": "0"
},
{
"input": "7\n2",
"output": "2"
},
{
"input": "100000\n0",
"output": "2"
},
{
"input": "100000\n1",
"output": "0"
},
{
"input": "100000\n2",
"output": "1"
},
{
"input": "99999\n1",
"output": "1"
},
{
"input": "99998\n1",
"output": "2"
},
{
"input": "99997\n1",
"output": "0"
},
{
"input": "99996\n1",
"output": "1"
},
{
"input": "99995\n1",
"output": "2"
},
{
"input": "1999999995\n0",
"output": "2"
},
{
"input": "1999999995\n1",
"output": "1"
},
{
"input": "1999999995\n2",
"output": "0"
},
{
"input": "1999999996\n0",
"output": "2"
},
{
"input": "1999999996\n1",
"output": "0"
},
{
"input": "1999999996\n2",
"output": "1"
},
{
"input": "1999999997\n0",
"output": "0"
},
{
"input": "1999999997\n1",
"output": "2"
},
{
"input": "1999999997\n2",
"output": "1"
},
{
"input": "1999999998\n0",
"output": "0"
},
{
"input": "1999999998\n1",
"output": "1"
},
{
"input": "1999999998\n2",
"output": "2"
},
{
"input": "1999999999\n0",
"output": "1"
},
{
"input": "1999999999\n1",
"output": "0"
},
{
"input": "1999999999\n2",
"output": "2"
},
{
"input": "2000000000\n1",
"output": "2"
},
{
"input": "2000000000\n2",
"output": "0"
},
{
"input": "1234567890\n0",
"output": "0"
},
{
"input": "1234567890\n1",
"output": "1"
},
{
"input": "1234567890\n2",
"output": "2"
},
{
"input": "123456789\n0",
"output": "2"
},
{
"input": "123456789\n1",
"output": "1"
},
{
"input": "123456789\n2",
"output": "0"
},
{
"input": "123456790\n0",
"output": "2"
},
{
"input": "12\n2",
"output": "2"
},
{
"input": "32\n1",
"output": "2"
},
{
"input": "20\n2",
"output": "0"
},
{
"input": "10\n1",
"output": "0"
},
{
"input": "1\n0",
"output": "1"
},
{
"input": "76994383\n1",
"output": "0"
},
{
"input": "25\n2",
"output": "2"
},
{
"input": "1\n2",
"output": "2"
},
{
"input": "12\n0",
"output": "0"
},
{
"input": "150\n2",
"output": "2"
},
{
"input": "15\n0",
"output": "2"
},
{
"input": "21\n2",
"output": "0"
},
{
"input": "18\n2",
"output": "2"
},
{
"input": "8\n2",
"output": "0"
},
{
"input": "10\n0",
"output": "2"
},
{
"input": "16\n0",
"output": "2"
}
] | 1,698,766,681
| 2,147,483,647
|
PyPy 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 6
| 500
| 2,048,000
|
from sys import stdin, stdout
from functools import reduce
def main():
n=int(stdin.readline().strip())
pos=int(stdin.readline().strip())
while n >0:
if n%2==0:
if pos==2: pos=1
elif pos==1: pos=2
else:
if pos==0: pos=1
elif pos==1: pos=0
n-=1
return pos
stdout.write(str(main()))
|
Title: Shell Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Bomboslav likes to look out of the window in his room and watch lads outside playing famous shell game. The game is played by two persons: operator and player. Operator takes three similar opaque shells and places a ball beneath one of them. Then he shuffles the shells by swapping some pairs and the player has to guess the current position of the ball.
Bomboslav noticed that guys are not very inventive, so the operator always swaps the left shell with the middle one during odd moves (first, third, fifth, etc.) and always swaps the middle shell with the right one during even moves (second, fourth, etc.).
Let's number shells from 0 to 2 from left to right. Thus the left shell is assigned number 0, the middle shell is 1 and the right shell is 2. Bomboslav has missed the moment when the ball was placed beneath the shell, but he knows that exactly *n* movements were made by the operator and the ball was under shell *x* at the end. Now he wonders, what was the initial position of the ball?
Input Specification:
The first line of the input contains an integer *n* (1<=≤<=*n*<=≤<=2·109) — the number of movements made by the operator.
The second line contains a single integer *x* (0<=≤<=*x*<=≤<=2) — the index of the shell where the ball was found after *n* movements.
Output Specification:
Print one integer from 0 to 2 — the index of the shell where the ball was initially placed.
Demo Input:
['4\n2\n', '1\n1\n']
Demo Output:
['1\n', '0\n']
Note:
In the first sample, the ball was initially placed beneath the middle shell and the operator completed four movements.
1. During the first move operator swapped the left shell and the middle shell. The ball is now under the left shell. 1. During the second move operator swapped the middle shell and the right one. The ball is still under the left shell. 1. During the third move operator swapped the left shell and the middle shell again. The ball is again in the middle. 1. Finally, the operators swapped the middle shell and the right shell. The ball is now beneath the right shell.
|
```python
from sys import stdin, stdout
from functools import reduce
def main():
n=int(stdin.readline().strip())
pos=int(stdin.readline().strip())
while n >0:
if n%2==0:
if pos==2: pos=1
elif pos==1: pos=2
else:
if pos==0: pos=1
elif pos==1: pos=0
n-=1
return pos
stdout.write(str(main()))
```
| 0
|
|
698
|
A
|
Vacations
|
PROGRAMMING
| 1,400
|
[
"dp"
] | null | null |
Vasya has *n* days of vacations! So he decided to improve his IT skills and do sport. Vasya knows the following information about each of this *n* days: whether that gym opened and whether a contest was carried out in the Internet on that day. For the *i*-th day there are four options:
1. on this day the gym is closed and the contest is not carried out; 1. on this day the gym is closed and the contest is carried out; 1. on this day the gym is open and the contest is not carried out; 1. on this day the gym is open and the contest is carried out.
On each of days Vasya can either have a rest or write the contest (if it is carried out on this day), or do sport (if the gym is open on this day).
Find the minimum number of days on which Vasya will have a rest (it means, he will not do sport and write the contest at the same time). The only limitation that Vasya has — he does not want to do the same activity on two consecutive days: it means, he will not do sport on two consecutive days, and write the contest on two consecutive days.
|
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100) — the number of days of Vasya's vacations.
The second line contains the sequence of integers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=≤<=3) separated by space, where:
- *a**i* equals 0, if on the *i*-th day of vacations the gym is closed and the contest is not carried out; - *a**i* equals 1, if on the *i*-th day of vacations the gym is closed, but the contest is carried out; - *a**i* equals 2, if on the *i*-th day of vacations the gym is open and the contest is not carried out; - *a**i* equals 3, if on the *i*-th day of vacations the gym is open and the contest is carried out.
|
Print the minimum possible number of days on which Vasya will have a rest. Remember that Vasya refuses:
- to do sport on any two consecutive days, - to write the contest on any two consecutive days.
|
[
"4\n1 3 2 0\n",
"7\n1 3 3 2 1 2 3\n",
"2\n2 2\n"
] |
[
"2\n",
"0\n",
"1\n"
] |
In the first test Vasya can write the contest on the day number 1 and do sport on the day number 3. Thus, he will have a rest for only 2 days.
In the second test Vasya should write contests on days number 1, 3, 5 and 7, in other days do sport. Thus, he will not have a rest for a single day.
In the third test Vasya can do sport either on a day number 1 or number 2. He can not do sport in two days, because it will be contrary to the his limitation. Thus, he will have a rest for only one day.
| 500
|
[
{
"input": "4\n1 3 2 0",
"output": "2"
},
{
"input": "7\n1 3 3 2 1 2 3",
"output": "0"
},
{
"input": "2\n2 2",
"output": "1"
},
{
"input": "1\n0",
"output": "1"
},
{
"input": "10\n0 0 1 1 0 0 0 0 1 0",
"output": "8"
},
{
"input": "100\n3 2 3 3 3 2 3 1 3 2 2 3 2 3 3 3 3 3 3 1 2 2 3 1 3 3 2 2 2 3 1 0 3 3 3 2 3 3 1 1 3 1 3 3 3 1 3 1 3 0 1 3 2 3 2 1 1 3 2 3 3 3 2 3 1 3 3 3 3 2 2 2 1 3 1 3 3 3 3 1 3 2 3 3 0 3 3 3 3 3 1 0 2 1 3 3 0 2 3 3",
"output": "16"
},
{
"input": "10\n2 3 0 1 3 1 2 2 1 0",
"output": "3"
},
{
"input": "45\n3 3 2 3 2 3 3 3 0 3 3 3 3 3 3 3 1 3 2 3 2 3 2 2 2 3 2 3 3 3 3 3 1 2 3 3 2 2 2 3 3 3 3 1 3",
"output": "6"
},
{
"input": "1\n1",
"output": "0"
},
{
"input": "1\n2",
"output": "0"
},
{
"input": "1\n3",
"output": "0"
},
{
"input": "2\n1 1",
"output": "1"
},
{
"input": "2\n1 3",
"output": "0"
},
{
"input": "2\n0 1",
"output": "1"
},
{
"input": "2\n0 0",
"output": "2"
},
{
"input": "2\n3 3",
"output": "0"
},
{
"input": "3\n3 3 3",
"output": "0"
},
{
"input": "2\n3 2",
"output": "0"
},
{
"input": "2\n0 2",
"output": "1"
},
{
"input": "10\n2 2 3 3 3 3 2 1 3 2",
"output": "2"
},
{
"input": "15\n0 1 0 0 0 2 0 1 0 0 0 2 0 0 0",
"output": "11"
},
{
"input": "15\n1 3 2 2 2 3 3 3 3 2 3 2 2 1 1",
"output": "4"
},
{
"input": "15\n3 1 3 2 3 2 2 2 3 3 3 3 2 3 2",
"output": "3"
},
{
"input": "20\n0 2 0 1 0 0 0 1 2 0 1 1 1 0 1 1 0 1 1 0",
"output": "12"
},
{
"input": "20\n2 3 2 3 3 3 3 2 0 3 1 1 2 3 0 3 2 3 0 3",
"output": "5"
},
{
"input": "20\n3 3 3 3 2 3 3 2 1 3 3 2 2 2 3 2 2 2 2 2",
"output": "4"
},
{
"input": "25\n0 0 1 0 0 1 0 0 1 0 0 1 0 2 0 0 2 0 0 1 0 2 0 1 1",
"output": "16"
},
{
"input": "25\n1 3 3 2 2 3 3 3 3 3 1 2 2 3 2 0 2 1 0 1 3 2 2 3 3",
"output": "5"
},
{
"input": "25\n2 3 1 3 3 2 1 3 3 3 1 3 3 1 3 2 3 3 1 3 3 3 2 3 3",
"output": "3"
},
{
"input": "30\n0 0 1 0 1 0 1 1 0 0 0 0 0 0 1 0 0 1 1 0 0 2 0 0 1 1 2 0 0 0",
"output": "22"
},
{
"input": "30\n1 1 3 2 2 0 3 2 3 3 1 2 0 1 1 2 3 3 2 3 1 3 2 3 0 2 0 3 3 2",
"output": "9"
},
{
"input": "30\n1 2 3 2 2 3 3 3 3 3 3 3 3 3 3 1 2 2 3 2 3 3 3 2 1 3 3 3 1 3",
"output": "2"
},
{
"input": "35\n0 1 1 0 0 2 0 0 1 0 0 0 1 0 1 0 1 0 0 0 1 2 1 0 2 2 1 0 1 0 1 1 1 0 0",
"output": "21"
},
{
"input": "35\n2 2 0 3 2 2 0 3 3 1 1 3 3 1 2 2 0 2 2 2 2 3 1 0 2 1 3 2 2 3 2 3 3 1 2",
"output": "11"
},
{
"input": "35\n1 2 2 3 3 3 3 3 2 2 3 3 2 3 3 2 3 2 3 3 2 2 2 3 3 2 3 3 3 1 3 3 2 2 2",
"output": "7"
},
{
"input": "40\n2 0 1 1 0 0 0 0 2 0 1 1 1 0 0 1 0 0 0 0 0 2 0 0 0 2 1 1 1 3 0 0 0 0 0 0 0 1 1 0",
"output": "28"
},
{
"input": "40\n2 2 3 2 0 2 3 2 1 2 3 0 2 3 2 1 1 3 1 1 0 2 3 1 3 3 1 1 3 3 2 2 1 3 3 3 2 3 3 1",
"output": "10"
},
{
"input": "40\n1 3 2 3 3 2 3 3 2 2 3 1 2 1 2 2 3 1 2 2 1 2 2 2 1 2 2 3 2 3 2 3 2 3 3 3 1 3 2 3",
"output": "8"
},
{
"input": "45\n2 1 0 0 0 2 1 0 1 0 0 2 2 1 1 0 0 2 0 0 0 0 0 0 1 0 0 2 0 0 1 1 0 0 1 0 0 1 1 2 0 0 2 0 2",
"output": "29"
},
{
"input": "45\n3 3 2 3 3 3 2 2 3 2 3 1 3 2 3 2 2 1 1 3 2 3 2 1 3 1 2 3 2 2 0 3 3 2 3 2 3 2 3 2 0 3 1 1 3",
"output": "8"
},
{
"input": "50\n3 0 0 0 2 0 0 0 0 0 0 0 2 1 0 2 0 1 0 1 3 0 2 1 1 0 0 1 1 0 0 1 2 1 1 2 1 1 0 0 0 0 0 0 0 1 2 2 0 0",
"output": "32"
},
{
"input": "50\n3 3 3 3 1 0 3 3 0 2 3 1 1 1 3 2 3 3 3 3 3 1 0 1 2 2 3 3 2 3 0 0 0 2 1 0 1 2 2 2 2 0 2 2 2 1 2 3 3 2",
"output": "16"
},
{
"input": "50\n3 2 3 1 2 1 2 3 3 2 3 3 2 1 3 3 3 3 3 3 2 3 2 3 2 2 3 3 3 2 3 3 3 3 2 3 1 2 3 3 2 3 3 1 2 2 1 1 3 3",
"output": "7"
},
{
"input": "55\n0 0 1 1 0 1 0 0 1 0 1 0 0 0 2 0 0 1 0 0 0 1 0 0 0 0 3 1 0 0 0 1 0 0 0 0 2 0 0 0 2 0 2 1 0 0 0 0 0 0 0 0 2 0 0",
"output": "40"
},
{
"input": "55\n3 0 3 3 3 2 0 2 3 0 3 2 3 3 0 3 3 1 3 3 1 2 3 2 0 3 3 2 1 2 3 2 3 0 3 2 2 1 2 3 2 2 1 3 2 2 3 1 3 2 2 3 3 2 2",
"output": "13"
},
{
"input": "55\n3 3 1 3 2 3 2 3 2 2 3 3 3 3 3 1 1 3 3 2 3 2 3 2 0 1 3 3 3 3 2 3 2 3 1 1 2 2 2 3 3 3 3 3 2 2 2 3 2 3 3 3 3 1 3",
"output": "7"
},
{
"input": "60\n0 1 0 0 0 0 0 0 0 2 1 1 3 0 0 0 0 0 1 0 1 1 0 0 0 3 0 1 0 1 0 2 0 0 0 0 0 1 0 0 0 0 1 1 0 1 0 0 0 0 0 1 0 0 1 0 1 0 0 0",
"output": "44"
},
{
"input": "60\n3 2 1 3 2 2 3 3 3 1 1 3 2 2 3 3 1 3 2 2 3 3 2 2 2 2 0 2 2 3 2 3 0 3 3 3 2 3 3 0 1 3 2 1 3 1 1 2 1 3 1 1 2 2 1 3 3 3 2 2",
"output": "15"
},
{
"input": "60\n3 2 2 3 2 3 2 3 3 2 3 2 3 3 2 3 3 3 3 3 3 2 3 3 1 2 3 3 3 2 1 3 3 1 3 1 3 0 3 3 3 2 3 2 3 2 3 3 1 1 2 3 3 3 3 2 1 3 2 3",
"output": "8"
},
{
"input": "65\n1 0 2 1 1 0 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 0 1 2 0 2 1 0 2 1 0 1 0 1 1 0 1 1 1 2 1 0 1 0 0 0 0 1 2 2 1 0 0 1 2 1 2 0 2 0 0 0 1 1",
"output": "35"
},
{
"input": "65\n2 2 2 3 0 2 1 2 3 3 1 3 1 2 1 3 2 3 2 2 2 1 2 0 3 1 3 1 1 3 1 3 3 3 3 3 1 3 0 3 1 3 1 2 2 3 2 0 3 1 3 2 1 2 2 2 3 3 2 3 3 3 2 2 3",
"output": "13"
},
{
"input": "65\n3 2 3 3 3 2 3 2 3 3 3 3 3 3 3 3 3 2 3 2 3 2 2 3 3 3 3 3 2 2 2 3 3 2 3 3 2 3 3 3 3 2 3 3 3 2 2 3 3 3 3 3 3 2 2 3 3 2 3 3 1 3 3 3 3",
"output": "6"
},
{
"input": "70\n1 0 0 0 1 0 1 0 0 0 1 1 0 1 0 0 1 1 1 0 1 1 0 0 1 1 1 3 1 1 0 1 2 0 2 1 0 0 0 1 1 1 1 1 0 0 1 0 0 0 1 1 1 3 0 0 1 0 0 0 1 0 0 0 0 0 1 0 1 1",
"output": "43"
},
{
"input": "70\n2 3 3 3 1 3 3 1 2 1 1 2 2 3 0 2 3 3 1 3 3 2 2 3 3 3 2 2 2 2 1 3 3 0 2 1 1 3 2 3 3 2 2 3 1 3 1 2 3 2 3 3 2 2 2 3 1 1 2 1 3 3 2 2 3 3 3 1 1 1",
"output": "16"
},
{
"input": "70\n3 3 2 2 1 2 1 2 2 2 2 2 3 3 2 3 3 3 3 2 2 2 2 3 3 3 1 3 3 3 2 3 3 3 3 2 3 3 1 3 1 3 2 3 3 2 3 3 3 2 3 2 3 3 1 2 3 3 2 2 2 3 2 3 3 3 3 3 3 1",
"output": "10"
},
{
"input": "75\n1 0 0 1 1 0 0 1 0 1 2 0 0 2 1 1 0 0 0 0 0 0 2 1 1 0 0 0 0 1 0 1 0 1 1 1 0 1 0 0 1 0 0 0 0 0 0 1 1 0 0 1 2 1 0 0 0 0 0 0 0 1 0 0 0 1 0 0 0 1 1 1 0 1 0",
"output": "51"
},
{
"input": "75\n1 3 3 3 1 1 3 2 3 3 1 3 3 3 2 1 3 2 2 3 1 1 1 1 1 1 2 3 3 3 3 3 3 2 3 3 3 3 3 2 3 3 2 2 2 1 2 3 3 2 2 3 0 1 1 3 3 0 0 1 1 3 2 3 3 3 3 1 2 2 3 3 3 3 1",
"output": "16"
},
{
"input": "75\n3 3 3 3 2 2 3 2 2 3 2 2 1 2 3 3 2 2 3 3 1 2 2 2 1 3 3 3 1 2 2 3 3 3 2 3 2 2 2 3 3 1 3 2 2 3 3 3 0 3 2 1 3 3 2 3 3 3 3 1 2 3 3 3 2 2 3 3 3 3 2 2 3 3 1",
"output": "11"
},
{
"input": "80\n0 0 0 0 2 0 1 1 1 1 1 0 0 0 0 2 0 0 1 0 0 0 0 1 1 0 2 2 1 1 0 1 0 1 0 1 1 1 0 1 2 1 1 0 0 0 1 1 0 1 1 0 1 0 0 1 0 0 1 0 0 0 0 0 0 0 2 2 0 1 1 0 0 0 0 0 0 0 0 1",
"output": "56"
},
{
"input": "80\n2 2 3 3 2 1 0 1 0 3 2 2 3 2 1 3 1 3 3 2 3 3 3 2 3 3 3 2 1 3 3 1 3 3 3 3 3 3 2 2 2 1 3 2 1 3 2 1 1 0 1 1 2 1 3 0 1 2 3 2 2 3 2 3 1 3 3 2 1 1 0 3 3 3 3 1 2 1 2 0",
"output": "17"
},
{
"input": "80\n2 3 3 2 2 2 3 3 2 3 3 3 3 3 2 3 2 3 2 3 3 3 3 3 3 3 3 3 2 3 1 3 2 3 3 0 3 1 2 3 3 1 2 3 2 3 3 2 3 3 3 3 3 2 2 3 0 3 3 3 3 3 2 2 3 2 3 3 3 3 3 2 3 2 3 3 3 3 2 3",
"output": "9"
},
{
"input": "85\n0 1 1 0 0 0 0 0 0 1 0 0 0 1 0 0 0 0 2 0 1 0 0 2 0 1 1 0 0 0 0 2 2 0 0 0 1 0 0 0 1 2 0 1 0 0 0 2 1 1 2 0 3 1 0 2 2 1 0 0 1 1 0 0 0 0 1 0 2 1 1 2 1 0 0 1 2 1 2 0 0 1 0 1 0",
"output": "54"
},
{
"input": "85\n2 3 1 3 2 3 1 3 3 2 1 2 1 2 2 3 2 2 3 2 0 3 3 2 1 2 2 2 3 3 2 3 3 3 2 1 1 3 1 3 2 2 2 3 3 2 3 2 3 1 1 3 2 3 1 3 3 2 3 3 2 2 3 0 1 1 2 2 2 2 1 2 3 1 3 3 1 3 2 2 3 2 3 3 3",
"output": "19"
},
{
"input": "85\n1 2 1 2 3 2 3 3 3 3 3 3 3 2 1 3 2 3 3 3 3 2 3 3 3 1 3 3 3 3 2 3 3 3 3 3 3 2 2 1 3 3 3 3 2 2 3 1 1 2 3 3 3 2 3 3 3 3 3 2 3 3 3 2 2 3 3 1 1 1 3 3 3 3 1 3 3 3 1 3 3 1 3 2 3",
"output": "9"
},
{
"input": "90\n2 0 1 0 0 0 0 0 0 1 1 2 0 0 0 0 0 0 0 2 2 0 2 0 0 2 1 0 2 0 1 0 1 0 0 1 2 2 0 0 1 0 0 1 0 1 0 2 0 1 1 1 0 1 1 0 1 0 2 0 1 0 1 0 0 0 1 0 0 1 2 0 0 0 1 0 0 2 2 0 0 0 0 0 1 3 1 1 0 1",
"output": "57"
},
{
"input": "90\n2 3 3 3 2 3 2 1 3 0 3 2 3 3 2 1 3 3 2 3 2 3 3 2 1 3 1 3 3 1 2 2 3 3 2 1 2 3 2 3 0 3 3 2 2 3 1 0 3 3 1 3 3 3 3 2 1 2 2 1 3 2 1 3 3 1 2 0 2 2 3 2 2 3 3 3 1 3 2 1 2 3 3 2 3 2 3 3 2 1",
"output": "17"
},
{
"input": "90\n2 3 2 3 2 2 3 3 2 3 2 1 2 3 3 3 2 3 2 3 3 2 3 3 3 1 3 3 1 3 2 3 2 2 1 3 3 3 3 3 3 3 3 3 3 2 3 2 3 2 1 3 3 3 3 2 2 3 3 3 3 3 3 3 3 3 3 3 3 2 2 3 3 3 3 1 3 2 3 3 3 2 2 3 2 3 2 1 3 2",
"output": "9"
},
{
"input": "95\n0 0 3 0 2 0 1 0 0 2 0 0 0 0 0 0 0 1 0 0 0 2 0 0 0 0 0 1 0 0 2 1 0 0 1 0 0 0 1 0 0 0 0 1 0 1 0 0 1 0 1 2 0 1 2 2 0 0 1 0 2 0 0 0 1 0 2 1 2 1 0 1 0 0 0 1 0 0 1 1 2 1 1 1 1 2 0 0 0 0 0 1 1 0 1",
"output": "61"
},
{
"input": "95\n2 3 3 2 1 1 3 3 3 2 3 3 3 2 3 2 3 3 3 2 3 2 2 3 3 2 1 2 3 3 3 1 3 0 3 3 1 3 3 1 0 1 3 3 3 0 2 1 3 3 3 3 0 1 3 2 3 3 2 1 3 1 2 1 1 2 3 0 3 3 2 1 3 2 1 3 3 3 2 2 3 2 3 3 3 2 1 3 3 3 2 3 3 1 2",
"output": "15"
},
{
"input": "95\n2 3 3 2 3 2 2 1 3 1 2 1 2 3 1 2 3 3 1 3 3 3 1 2 3 2 2 2 2 3 3 3 2 2 3 3 3 3 3 1 2 2 3 3 3 3 2 3 2 2 2 3 3 2 3 3 3 3 3 3 3 0 3 2 0 3 3 1 3 3 3 2 3 2 3 2 3 3 3 3 2 2 1 1 3 3 3 3 3 1 3 3 3 3 2",
"output": "14"
},
{
"input": "100\n1 0 2 0 0 0 0 2 0 0 0 1 0 1 0 0 1 0 1 2 0 1 1 0 0 1 0 1 1 0 0 0 2 0 1 0 0 2 0 0 0 0 0 1 1 1 0 0 1 0 2 0 0 0 0 1 0 1 0 1 0 1 0 1 2 2 0 0 2 0 1 0 1 0 1 0 0 0 1 0 0 2 1 1 1 0 0 1 0 0 0 2 0 0 2 1 1 0 0 2",
"output": "63"
},
{
"input": "100\n3 2 1 3 2 3 2 3 2 2 3 1 3 3 3 3 3 2 2 3 2 2 3 2 3 3 3 2 3 1 2 1 3 3 3 3 1 3 3 3 3 3 2 3 2 1 3 3 1 2 2 3 1 3 3 1 2 2 1 3 1 3 2 2 3 3 1 3 2 3 1 2 1 2 3 3 2 2 1 2 3 3 3 3 3 1 3 3 3 3 2 1 3 0 3 3 3 2 3 3",
"output": "15"
},
{
"input": "100\n1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2",
"output": "0"
},
{
"input": "100\n3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3",
"output": "0"
},
{
"input": "100\n1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1",
"output": "50"
},
{
"input": "100\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2",
"output": "50"
},
{
"input": "99\n1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1",
"output": "49"
},
{
"input": "100\n2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1 2 1",
"output": "0"
},
{
"input": "100\n0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0",
"output": "100"
},
{
"input": "2\n0 3",
"output": "1"
},
{
"input": "2\n1 0",
"output": "1"
},
{
"input": "2\n1 2",
"output": "0"
},
{
"input": "2\n2 0",
"output": "1"
},
{
"input": "2\n2 1",
"output": "0"
},
{
"input": "2\n2 3",
"output": "0"
},
{
"input": "2\n3 0",
"output": "1"
},
{
"input": "2\n3 1",
"output": "0"
},
{
"input": "100\n3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0 3 0",
"output": "50"
}
] | 1,563,775,891
| 2,147,483,647
|
PyPy 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 5
| 1,000
| 9,932,800
|
def workDays(days,index,prev_day,work):
if index < len(days):
allowed = ['R']
if days[index] == 1:
if prev_day != 'C':
allowed.append('C')
elif days[index] == 2:
if prev_day != 'G':
allowed.append('G')
elif days[index] == 3:
if prev_day == 'C':
allowed.append('G')
elif prev_day == 'G':
allowed.append('C')
else:
allowed.append('C')
allowed.append('G')
m = 0
#print(allowed,index,prev_day)
for i in allowed:
work.append(i)
m = max(m,workDays(days,index+1,i,work))
work.pop()
return m
else:
#print(work)
return len(days)-work.count('R')
def main():
n = int(input())
days = list(map(int,input().split()))
work = []
print(n-workDays(days,0,'R',work))
main()
|
Title: Vacations
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya has *n* days of vacations! So he decided to improve his IT skills and do sport. Vasya knows the following information about each of this *n* days: whether that gym opened and whether a contest was carried out in the Internet on that day. For the *i*-th day there are four options:
1. on this day the gym is closed and the contest is not carried out; 1. on this day the gym is closed and the contest is carried out; 1. on this day the gym is open and the contest is not carried out; 1. on this day the gym is open and the contest is carried out.
On each of days Vasya can either have a rest or write the contest (if it is carried out on this day), or do sport (if the gym is open on this day).
Find the minimum number of days on which Vasya will have a rest (it means, he will not do sport and write the contest at the same time). The only limitation that Vasya has — he does not want to do the same activity on two consecutive days: it means, he will not do sport on two consecutive days, and write the contest on two consecutive days.
Input Specification:
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100) — the number of days of Vasya's vacations.
The second line contains the sequence of integers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=≤<=3) separated by space, where:
- *a**i* equals 0, if on the *i*-th day of vacations the gym is closed and the contest is not carried out; - *a**i* equals 1, if on the *i*-th day of vacations the gym is closed, but the contest is carried out; - *a**i* equals 2, if on the *i*-th day of vacations the gym is open and the contest is not carried out; - *a**i* equals 3, if on the *i*-th day of vacations the gym is open and the contest is carried out.
Output Specification:
Print the minimum possible number of days on which Vasya will have a rest. Remember that Vasya refuses:
- to do sport on any two consecutive days, - to write the contest on any two consecutive days.
Demo Input:
['4\n1 3 2 0\n', '7\n1 3 3 2 1 2 3\n', '2\n2 2\n']
Demo Output:
['2\n', '0\n', '1\n']
Note:
In the first test Vasya can write the contest on the day number 1 and do sport on the day number 3. Thus, he will have a rest for only 2 days.
In the second test Vasya should write contests on days number 1, 3, 5 and 7, in other days do sport. Thus, he will not have a rest for a single day.
In the third test Vasya can do sport either on a day number 1 or number 2. He can not do sport in two days, because it will be contrary to the his limitation. Thus, he will have a rest for only one day.
|
```python
def workDays(days,index,prev_day,work):
if index < len(days):
allowed = ['R']
if days[index] == 1:
if prev_day != 'C':
allowed.append('C')
elif days[index] == 2:
if prev_day != 'G':
allowed.append('G')
elif days[index] == 3:
if prev_day == 'C':
allowed.append('G')
elif prev_day == 'G':
allowed.append('C')
else:
allowed.append('C')
allowed.append('G')
m = 0
#print(allowed,index,prev_day)
for i in allowed:
work.append(i)
m = max(m,workDays(days,index+1,i,work))
work.pop()
return m
else:
#print(work)
return len(days)-work.count('R')
def main():
n = int(input())
days = list(map(int,input().split()))
work = []
print(n-workDays(days,0,'R',work))
main()
```
| 0
|
|
778
|
A
|
String Game
|
PROGRAMMING
| 1,700
|
[
"binary search",
"greedy",
"strings"
] | null | null |
Little Nastya has a hobby, she likes to remove some letters from word, to obtain another word. But it turns out to be pretty hard for her, because she is too young. Therefore, her brother Sergey always helps her.
Sergey gives Nastya the word *t* and wants to get the word *p* out of it. Nastya removes letters in a certain order (one after another, in this order strictly), which is specified by permutation of letters' indices of the word *t*: *a*1... *a*|*t*|. We denote the length of word *x* as |*x*|. Note that after removing one letter, the indices of other letters don't change. For example, if *t*<==<="nastya" and *a*<==<=[4,<=1,<=5,<=3,<=2,<=6] then removals make the following sequence of words "nastya" "nastya" "nastya" "nastya" "nastya" "nastya" "nastya".
Sergey knows this permutation. His goal is to stop his sister at some point and continue removing by himself to get the word *p*. Since Nastya likes this activity, Sergey wants to stop her as late as possible. Your task is to determine, how many letters Nastya can remove before she will be stopped by Sergey.
It is guaranteed that the word *p* can be obtained by removing the letters from word *t*.
|
The first and second lines of the input contain the words *t* and *p*, respectively. Words are composed of lowercase letters of the Latin alphabet (1<=≤<=|*p*|<=<<=|*t*|<=≤<=200<=000). It is guaranteed that the word *p* can be obtained by removing the letters from word *t*.
Next line contains a permutation *a*1,<=*a*2,<=...,<=*a*|*t*| of letter indices that specifies the order in which Nastya removes letters of *t* (1<=≤<=*a**i*<=≤<=|*t*|, all *a**i* are distinct).
|
Print a single integer number, the maximum number of letters that Nastya can remove.
|
[
"ababcba\nabb\n5 3 4 1 7 6 2\n",
"bbbabb\nbb\n1 6 3 4 2 5\n"
] |
[
"3",
"4"
] |
In the first sample test sequence of removing made by Nastya looks like this:
"ababcba" <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> "ababcba" <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> "ababcba" <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> "ababcba"
Nastya can not continue, because it is impossible to get word "abb" from word "ababcba".
So, Nastya will remove only three letters.
| 500
|
[
{
"input": "ababcba\nabb\n5 3 4 1 7 6 2",
"output": "3"
},
{
"input": "bbbabb\nbb\n1 6 3 4 2 5",
"output": "4"
},
{
"input": "cacaccccccacccc\ncacc\n10 9 14 5 1 7 15 3 6 12 4 8 11 13 2",
"output": "9"
},
{
"input": "aaaabaaabaabaaaaaaaa\naaaa\n18 5 4 6 13 9 1 3 7 8 16 10 12 19 17 15 14 11 20 2",
"output": "16"
},
{
"input": "aaaaaaaadbaaabbbbbddaaabdadbbbbbdbbabbbabaabdbbdababbbddddbdaabbddbbbbabbbbbabadaadabaaaadbbabbbaddb\naaaaaaaaaaaaaa\n61 52 5 43 53 81 7 96 6 9 34 78 79 12 8 63 22 76 18 46 41 56 3 20 57 21 75 73 100 94 35 69 32 4 70 95 88 44 68 10 71 98 23 89 36 62 28 51 24 30 74 55 27 80 38 48 93 1 19 84 13 11 86 60 87 33 39 29 83 91 67 72 54 2 17 85 82 14 15 90 64 50 99 26 66 65 31 49 40 45 77 37 25 42 97 47 58 92 59 16",
"output": "57"
}
] | 1,598,245,445
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 29
| 592
| 45,465,600
|
from collections import defaultdict
def isSubsequence(S,T,List,pos,Pos):
lenS = len(S)
lenT = len(T)
Sx = 0
Tx = 0
while(Tx<lenT and Sx<lenS):
if(Pos[Sx]<pos):
Sx+=1
elif(S[Sx] == T[Tx]):
Sx+=1
Tx+=1
else:
Sx+=1
if(Tx == lenT):
return True
return False
S = input()
T = input()
List = [int(x) for x in input().split()]
N = len(List)
Pos = defaultdict(int)
for i in range(N):
Pos[List[i]-1] = i
N = len(List)
l = 0
r = N-1
while(l<r):
mid = (l+r)>>1
if(isSubsequence(S,T,List,mid,Pos)):
l = mid+1
else:
r = mid
print(l-1)
|
Title: String Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Little Nastya has a hobby, she likes to remove some letters from word, to obtain another word. But it turns out to be pretty hard for her, because she is too young. Therefore, her brother Sergey always helps her.
Sergey gives Nastya the word *t* and wants to get the word *p* out of it. Nastya removes letters in a certain order (one after another, in this order strictly), which is specified by permutation of letters' indices of the word *t*: *a*1... *a*|*t*|. We denote the length of word *x* as |*x*|. Note that after removing one letter, the indices of other letters don't change. For example, if *t*<==<="nastya" and *a*<==<=[4,<=1,<=5,<=3,<=2,<=6] then removals make the following sequence of words "nastya" "nastya" "nastya" "nastya" "nastya" "nastya" "nastya".
Sergey knows this permutation. His goal is to stop his sister at some point and continue removing by himself to get the word *p*. Since Nastya likes this activity, Sergey wants to stop her as late as possible. Your task is to determine, how many letters Nastya can remove before she will be stopped by Sergey.
It is guaranteed that the word *p* can be obtained by removing the letters from word *t*.
Input Specification:
The first and second lines of the input contain the words *t* and *p*, respectively. Words are composed of lowercase letters of the Latin alphabet (1<=≤<=|*p*|<=<<=|*t*|<=≤<=200<=000). It is guaranteed that the word *p* can be obtained by removing the letters from word *t*.
Next line contains a permutation *a*1,<=*a*2,<=...,<=*a*|*t*| of letter indices that specifies the order in which Nastya removes letters of *t* (1<=≤<=*a**i*<=≤<=|*t*|, all *a**i* are distinct).
Output Specification:
Print a single integer number, the maximum number of letters that Nastya can remove.
Demo Input:
['ababcba\nabb\n5 3 4 1 7 6 2\n', 'bbbabb\nbb\n1 6 3 4 2 5\n']
Demo Output:
['3', '4']
Note:
In the first sample test sequence of removing made by Nastya looks like this:
"ababcba" <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> "ababcba" <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> "ababcba" <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> "ababcba"
Nastya can not continue, because it is impossible to get word "abb" from word "ababcba".
So, Nastya will remove only three letters.
|
```python
from collections import defaultdict
def isSubsequence(S,T,List,pos,Pos):
lenS = len(S)
lenT = len(T)
Sx = 0
Tx = 0
while(Tx<lenT and Sx<lenS):
if(Pos[Sx]<pos):
Sx+=1
elif(S[Sx] == T[Tx]):
Sx+=1
Tx+=1
else:
Sx+=1
if(Tx == lenT):
return True
return False
S = input()
T = input()
List = [int(x) for x in input().split()]
N = len(List)
Pos = defaultdict(int)
for i in range(N):
Pos[List[i]-1] = i
N = len(List)
l = 0
r = N-1
while(l<r):
mid = (l+r)>>1
if(isSubsequence(S,T,List,mid,Pos)):
l = mid+1
else:
r = mid
print(l-1)
```
| 0
|
|
6
|
B
|
President's Office
|
PROGRAMMING
| 1,100
|
[
"implementation"
] |
B. President's Office
|
2
|
64
|
President of Berland has a very vast office-room, where, apart from him, work his subordinates. Each subordinate, as well as President himself, has his own desk of a unique colour. Each desk is rectangular, and its sides are parallel to the office walls. One day President decided to establish an assembly, of which all his deputies will be members. Unfortunately, he does not remember the exact amount of his deputies, but he remembers that the desk of each his deputy is adjacent to his own desk, that is to say, the two desks (President's and each deputy's) have a common side of a positive length.
The office-room plan can be viewed as a matrix with *n* rows and *m* columns. Each cell of this matrix is either empty, or contains a part of a desk. An uppercase Latin letter stands for each desk colour. The «period» character («.») stands for an empty cell.
|
The first line contains two separated by a space integer numbers *n*, *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the length and the width of the office-room, and *c* character — the President's desk colour. The following *n* lines contain *m* characters each — the office-room description. It is guaranteed that the colour of each desk is unique, and each desk represents a continuous subrectangle of the given matrix. All colours are marked by uppercase Latin letters.
|
Print the only number — the amount of President's deputies.
|
[
"3 4 R\nG.B.\n.RR.\nTTT.\n",
"3 3 Z\n...\n.H.\n..Z\n"
] |
[
"2\n",
"0\n"
] |
none
| 0
|
[
{
"input": "3 4 R\nG.B.\n.RR.\nTTT.",
"output": "2"
},
{
"input": "3 3 Z\n...\n.H.\n..Z",
"output": "0"
},
{
"input": "1 1 C\nC",
"output": "0"
},
{
"input": "2 2 W\nKW\nKW",
"output": "1"
},
{
"input": "1 10 H\n....DDHHHH",
"output": "1"
},
{
"input": "3 2 W\nOO\nWW\nWW",
"output": "1"
},
{
"input": "3 3 U\nUOO\nUVV\nUVV",
"output": "2"
},
{
"input": "4 5 Z\n...ZZ\nUU.ZZ\nUUTT.\n..TT.",
"output": "1"
},
{
"input": "4 4 X\nT..R\nTJJJ\nDJJJ\nXJJJ",
"output": "2"
},
{
"input": "5 5 O\nCQGAV\nIHTUD\nRFPZO\nMYSKX\nJEWBN",
"output": "3"
},
{
"input": "5 4 O\n.O.J\nWOBJ\nWOBJ\nDDBJ\nDD.J",
"output": "3"
},
{
"input": "7 7 Q\n....RRR\nUUUURRR\nUUUUSS.\n....SSB\nPPP.OIB\n.MMTTIB\nQQQTTIB",
"output": "2"
},
{
"input": "8 10 B\n..BBBBEEEE\n..BBBBEEEE\n..BBBBEEEE\n..BBBBEEEE\nJJJJYYYY..\nJJJJYYYY..\nJJJJYYYY..\nJJJJYYYY..",
"output": "3"
},
{
"input": "7 13 G\n....GGGGGGXXX\nSSSSGGGGGGXXX\nSSSSJJFFFFFFF\nRRR.JJFFFFFFF\nRRRYYYYYYYAAA\nRRRYYYYYYYAAA\nRRR.......AAA",
"output": "4"
},
{
"input": "10 10 T\nCCEEEKKKHJ\nCCRRRRRRHJ\nCC..XFFOOO\nZZZZZFFOOO\n..PTTFFOOO\nAAATTFFOOO\nAAATTYYYYY\nAAATTYYYYY\nAAAMMYYYYY\nAAA..YYYYY",
"output": "6"
},
{
"input": "15 12 M\n............\n.....L..QQQQ\nNNN..L..QQQQ\nNNN..LJJJJJ.\nNNNEEEEEEEE.\nNNNEEEEEEEE.\nNNNMMMMM.AAA\nNNNMMMMM.AAA\n.RRMMMMM.AAA\n.RRMMMMMYAAA\n.RRMMMMMYAAA\n.RRMMMMMYAAA\nZRRMMMMMYAAA\nZRRMMMMM.AAA\nZRRMMMMM.AAA",
"output": "4"
}
] | 1,634,566,180
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 32
| 61
| 0
|
n, m, c = input().split()
n, m = int(n), int(m)
d = [input() for i in range(int(n))]
dir = [[0, 1], [1, 0], [0, -1], [-1, 0]]
ad = {c, '.'}
for i in range(n):
for j in range(m):
if d[i][j] == c:
for x, y in dir:
if 0 <= i + x < n and 0 <= j + y < m:
l = d[i + x][j + y]
if l not in ad:
ad.add(l)
print(len(ad) - 2)
|
Title: President's Office
Time Limit: 2 seconds
Memory Limit: 64 megabytes
Problem Description:
President of Berland has a very vast office-room, where, apart from him, work his subordinates. Each subordinate, as well as President himself, has his own desk of a unique colour. Each desk is rectangular, and its sides are parallel to the office walls. One day President decided to establish an assembly, of which all his deputies will be members. Unfortunately, he does not remember the exact amount of his deputies, but he remembers that the desk of each his deputy is adjacent to his own desk, that is to say, the two desks (President's and each deputy's) have a common side of a positive length.
The office-room plan can be viewed as a matrix with *n* rows and *m* columns. Each cell of this matrix is either empty, or contains a part of a desk. An uppercase Latin letter stands for each desk colour. The «period» character («.») stands for an empty cell.
Input Specification:
The first line contains two separated by a space integer numbers *n*, *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the length and the width of the office-room, and *c* character — the President's desk colour. The following *n* lines contain *m* characters each — the office-room description. It is guaranteed that the colour of each desk is unique, and each desk represents a continuous subrectangle of the given matrix. All colours are marked by uppercase Latin letters.
Output Specification:
Print the only number — the amount of President's deputies.
Demo Input:
['3 4 R\nG.B.\n.RR.\nTTT.\n', '3 3 Z\n...\n.H.\n..Z\n']
Demo Output:
['2\n', '0\n']
Note:
none
|
```python
n, m, c = input().split()
n, m = int(n), int(m)
d = [input() for i in range(int(n))]
dir = [[0, 1], [1, 0], [0, -1], [-1, 0]]
ad = {c, '.'}
for i in range(n):
for j in range(m):
if d[i][j] == c:
for x, y in dir:
if 0 <= i + x < n and 0 <= j + y < m:
l = d[i + x][j + y]
if l not in ad:
ad.add(l)
print(len(ad) - 2)
```
| 3.98475
|
515
|
C
|
Drazil and Factorial
|
PROGRAMMING
| 1,400
|
[
"greedy",
"math",
"sortings"
] | null | null |
Drazil is playing a math game with Varda.
Let's define for positive integer *x* as a product of factorials of its digits. For example, .
First, they choose a decimal number *a* consisting of *n* digits that contains at least one digit larger than 1. This number may possibly start with leading zeroes. Then they should find maximum positive number *x* satisfying following two conditions:
1. *x* doesn't contain neither digit 0 nor digit 1.
2. = .
Help friends find such number.
|
The first line contains an integer *n* (1<=≤<=*n*<=≤<=15) — the number of digits in *a*.
The second line contains *n* digits of *a*. There is at least one digit in *a* that is larger than 1. Number *a* may possibly contain leading zeroes.
|
Output a maximum possible integer satisfying the conditions above. There should be no zeroes and ones in this number decimal representation.
|
[
"4\n1234\n",
"3\n555\n"
] |
[
"33222\n",
"555\n"
] |
In the first case, <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/f5a4207f23215fddce977ab5ea9e9d2e7578fb52.png" style="max-width: 100.0%;max-height: 100.0%;"/>
| 1,000
|
[
{
"input": "4\n1234",
"output": "33222"
},
{
"input": "3\n555",
"output": "555"
},
{
"input": "15\n012345781234578",
"output": "7777553333222222222222"
},
{
"input": "1\n8",
"output": "7222"
},
{
"input": "10\n1413472614",
"output": "75333332222222"
},
{
"input": "8\n68931246",
"output": "77553333332222222"
},
{
"input": "7\n4424368",
"output": "75333332222222222"
},
{
"input": "6\n576825",
"output": "7755532222"
},
{
"input": "5\n97715",
"output": "7775332"
},
{
"input": "3\n915",
"output": "75332"
},
{
"input": "2\n26",
"output": "532"
},
{
"input": "1\n4",
"output": "322"
},
{
"input": "15\n028745260720699",
"output": "7777755533333332222222222"
},
{
"input": "13\n5761790121605",
"output": "7775555333322"
},
{
"input": "10\n3312667105",
"output": "755533332"
},
{
"input": "1\n7",
"output": "7"
},
{
"input": "15\n989898989898989",
"output": "777777777777777333333333333333322222222222222222222222222222"
},
{
"input": "15\n000000000000007",
"output": "7"
},
{
"input": "15\n999999999999990",
"output": "77777777777777333333333333333333333333333322222222222222"
},
{
"input": "1\n2",
"output": "2"
},
{
"input": "1\n3",
"output": "3"
},
{
"input": "1\n4",
"output": "322"
},
{
"input": "1\n5",
"output": "5"
},
{
"input": "1\n6",
"output": "53"
},
{
"input": "1\n7",
"output": "7"
},
{
"input": "1\n9",
"output": "7332"
},
{
"input": "2\n09",
"output": "7332"
},
{
"input": "13\n1337251172966",
"output": "777555333333222"
},
{
"input": "15\n987654329876543",
"output": "777777555533333333332222222222222"
},
{
"input": "9\n234567899",
"output": "777755333333322222222"
},
{
"input": "2\n99",
"output": "77333322"
},
{
"input": "2\n66",
"output": "5533"
},
{
"input": "3\n999",
"output": "777333333222"
},
{
"input": "5\n99999",
"output": "77777333333333322222"
},
{
"input": "9\n123456789",
"output": "77755333332222222"
},
{
"input": "9\n987654321",
"output": "77755333332222222"
},
{
"input": "3\n666",
"output": "555333"
},
{
"input": "2\n26",
"output": "532"
},
{
"input": "6\n555777",
"output": "777555"
},
{
"input": "10\n1234567899",
"output": "777755333333322222222"
},
{
"input": "4\n6666",
"output": "55553333"
},
{
"input": "4\n9754",
"output": "775333222"
},
{
"input": "2\n95",
"output": "75332"
},
{
"input": "14\n11122233344455",
"output": "55333333222222222"
},
{
"input": "12\n836544897832",
"output": "77777553333333222222222222222"
}
] | 1,644,118,568
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 3
| 46
| 0
|
n = int(input())
a = input()
if '0' not in a and '1' not in a:
print(a)
else:
hash_map = {
0: "0",
1: "0",
2: "2",
3: "3",
4: "322",
5: "5",
6: "53",
7: "7",
8: "7222",
9: "7332",
}
res = ''
for x in a:
if x != "0" and x != "1":
res += hash_map[int(x)]
res = sorted(res,reverse=True)
print(''.join(res))
|
Title: Drazil and Factorial
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Drazil is playing a math game with Varda.
Let's define for positive integer *x* as a product of factorials of its digits. For example, .
First, they choose a decimal number *a* consisting of *n* digits that contains at least one digit larger than 1. This number may possibly start with leading zeroes. Then they should find maximum positive number *x* satisfying following two conditions:
1. *x* doesn't contain neither digit 0 nor digit 1.
2. = .
Help friends find such number.
Input Specification:
The first line contains an integer *n* (1<=≤<=*n*<=≤<=15) — the number of digits in *a*.
The second line contains *n* digits of *a*. There is at least one digit in *a* that is larger than 1. Number *a* may possibly contain leading zeroes.
Output Specification:
Output a maximum possible integer satisfying the conditions above. There should be no zeroes and ones in this number decimal representation.
Demo Input:
['4\n1234\n', '3\n555\n']
Demo Output:
['33222\n', '555\n']
Note:
In the first case, <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/f5a4207f23215fddce977ab5ea9e9d2e7578fb52.png" style="max-width: 100.0%;max-height: 100.0%;"/>
|
```python
n = int(input())
a = input()
if '0' not in a and '1' not in a:
print(a)
else:
hash_map = {
0: "0",
1: "0",
2: "2",
3: "3",
4: "322",
5: "5",
6: "53",
7: "7",
8: "7222",
9: "7332",
}
res = ''
for x in a:
if x != "0" and x != "1":
res += hash_map[int(x)]
res = sorted(res,reverse=True)
print(''.join(res))
```
| 0
|
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