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brcktsrm
Problem description. Vipul is a hardworking super-hero who maintains the bracket ratio of all the strings in the world. Recently he indulged himself in saving the string population so much that he lost his ability for checking brackets (luckily, not permanently ).Being his super-hero friend help him in his time of hardship. Input The first line of the input contains an integer T denoting the number of test cases. The description of T test cases follows. The first line of each test case contains a single string S denoting the string to be checked. Output For each test case, output a single line printing "YES" or "NO" (without " " and in uppercase only) , denoting if the brackets in the given string is balanced or not . Constraints 1 ≤ T ≤ 10 1 ≤ length of S ≤ 60 Example Input: 3 ((())) (())() ()(() Output: YES YES NO   Explanation Example is self-explanatory.
{ "input": [ "3\n((()))\n(())()\n()(()" ], "output": [ "YES\nYES\nNO" ] }
{ "input": [], "output": [] }
CORRECT
python2
for _ in range(input()): try: eval(raw_input()) print 'YES' except TypeError: print 'YES' except: print 'NO'
brcktsrm
Problem description. Vipul is a hardworking super-hero who maintains the bracket ratio of all the strings in the world. Recently he indulged himself in saving the string population so much that he lost his ability for checking brackets (luckily, not permanently ).Being his super-hero friend help him in his time of hardship. Input The first line of the input contains an integer T denoting the number of test cases. The description of T test cases follows. The first line of each test case contains a single string S denoting the string to be checked. Output For each test case, output a single line printing "YES" or "NO" (without " " and in uppercase only) , denoting if the brackets in the given string is balanced or not . Constraints 1 ≤ T ≤ 10 1 ≤ length of S ≤ 60 Example Input: 3 ((())) (())() ()(() Output: YES YES NO   Explanation Example is self-explanatory.
{ "input": [ "3\n((()))\n(())()\n()(()" ], "output": [ "YES\nYES\nNO" ] }
{ "input": [], "output": [] }
CORRECT
python2
for _ in range(input()): ins = raw_input().strip() stck = [] res = "YES" for x in ins: if x == "(": stck.append(x) else: if len(stck)>0: stck.pop() else: res = "NO" break if len(stck) > 0: res = "NO" print res
brcktsrm
Problem description. Vipul is a hardworking super-hero who maintains the bracket ratio of all the strings in the world. Recently he indulged himself in saving the string population so much that he lost his ability for checking brackets (luckily, not permanently ).Being his super-hero friend help him in his time of hardship. Input The first line of the input contains an integer T denoting the number of test cases. The description of T test cases follows. The first line of each test case contains a single string S denoting the string to be checked. Output For each test case, output a single line printing "YES" or "NO" (without " " and in uppercase only) , denoting if the brackets in the given string is balanced or not . Constraints 1 ≤ T ≤ 10 1 ≤ length of S ≤ 60 Example Input: 3 ((())) (())() ()(() Output: YES YES NO   Explanation Example is self-explanatory.
{ "input": [ "3\n((()))\n(())()\n()(()" ], "output": [ "YES\nYES\nNO" ] }
{ "input": [], "output": [] }
CORRECT
python2
for _ in range(input()): try: eval(raw_input()); print 'YES' except TypeError: print 'YES' except: print 'NO'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math no_of_testcases = int(input()) for each in range(no_of_testcases): dist = int(input()) point_1 = map(int,raw_input().split()) point_2 = map(int,raw_input().split()) point_3 = map(int,raw_input().split()) point_12 =math.sqrt( math.pow((point_1[0] -point_2[0]),2) + math.pow((point_1[1] -point_2[1]),2)) point_23 =math.sqrt( math.pow((point_2[0] -point_3[0]),2) + math.pow((point_2[1] -point_3[1]),2)) point_31 =math.sqrt( math.pow((point_3[0] -point_1[0]),2) + math.pow((point_3[1] -point_1[1]),2)) count =0 if point_12 <= dist: count =count+1 if point_23 <= dist: count =count+1 if point_31 <= dist: count =count+1 if count >=2: print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def distance(x1,y1,x2,y2): dist = ((x1-x2)**2 + (y1-y2)**2)**0.5 return dist t = input() for i in range(t): r = input() chef_x,chef_y = map(int,raw_input().split(' ')) head_server_x,head_server_y = map(int,raw_input().split(' ')) sous_chef_x,sous_chef_y = map(int,raw_input().split(' ')) chef_head_server_distance = distance(chef_x,chef_y,head_server_x,head_server_y) chef_sous_chef_distance = distance(chef_x,chef_y,sous_chef_x,sous_chef_y) sous_chef_head_server_distance = distance(sous_chef_x, sous_chef_y, head_server_x, head_server_y) communicate = 0 if(chef_head_server_distance <= r): communicate+=1 if(chef_sous_chef_distance <= r): communicate+=1 if(sous_chef_head_server_distance <= r): communicate+=1 if(communicate >= 2): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
#COMM3 test = input() while test > 0: test -= 1 dist = input()**2 a,b = map(int, raw_input().split()) c,d = map(int, raw_input().split()) e,f = map(int, raw_input().split()) dist1 = (a-c)**2 + (b-d)**2 dist2 = (a-e)**2 + (b-f)**2 dist3 = (c-e)**2 + (d-f)**2 if (dist1 <= dist and dist2 <=dist) or (dist2 <= dist and dist3 <=dist) or (dist1 <= dist and dist3 <=dist): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from sys import stdin as ip for _ in xrange(int(ip.readline())): r=int(ip.readline())**2 a,b=map(int,ip.readline().split()) x,y=map(int,ip.readline().split()) p,q=map(int,ip.readline().split()) d1=pow(x-a,2)+pow(y-b,2) d2=pow(p-x,2)+pow(q-y,2) d3=pow(p-a,2)+pow(q-b,2) if d1<=r and d2<=r or d2<=r and d3<=r or d1<=r and d3<=r: print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math as m def leng(a,c,b,d): return m.sqrt(((a-c)**2)+((b-d)**2)) t=input() ans=[] for i in range(t): n=input() x1,y1=raw_input().split() x2,y2=raw_input().split() x3,y3=raw_input().split() d1=leng(int(x1),int(x2),int(y1),int(y2)) d2=leng(int(x1),int(x3),int(y1),int(y3)) d3=leng(int(x3),int(x2),int(y3),int(y2)) l=[d1,d2,d3] l.sort() if l[0]<=n and l[1]<=n and l[0]+l[1]>=l[2]: ans.append('yes') else: ans.append('no') for i in range(t): print ans[i]
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
t=input() def dist(a,b,c,d): return (((a-c)**2)+((b-d)**2))**0.5 for i in range(0,t): r=input() e=[] for j in range(0,3): e.append(map(int,raw_input().split(' '))) if dist(e[0][0],e[0][1],e[2][0],e[2][1])<=r: print "yes" elif dist(e[0][0],e[0][1],e[1][0],e[1][1])<=r and dist(e[1][0],e[1][1],e[2][0],e[2][1])<=r: print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
# -*- coding: utf-8 -*- """ Created on Wed Mar 16 12:29:47 2016 @author: matteoarno """ import sys data = sys.stdin.readlines() t = int(data.pop(0)) output = [] for i in range(t): r = int(data.pop(0)) chef = map(int,(data.pop(0).split(' '))) head = map(int,(data.pop(0).split(' '))) sous = map(int,(data.pop(0).split(' '))) def distance (first, second): dist = ((first[0]-second[0])**2 + (first[1]-second[1])**2)**(0.5) return dist ch = distance(chef, head) hs = distance(head, sous) cs = distance(chef, sous) if ch > r: if (hs <= r and cs <= r): output.append('yes') else: output.append('no') else: if (hs <= r or cs <= r): output.append('yes') else: output.append('no') for k in output: print k
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math def cal_dist(x1,y1,x2,y2): dis = math.sqrt(((x1-x2)**2)+((y1-y2)**2)) return dis test = int(input()) while test: R = int(input()) cx1,cy1=map(int, raw_input().split()) cx2,cy2=map(int, raw_input().split()) cx3,cy3=map(int, raw_input().split()) d1 = cal_dist(cx1,cy1,cx2,cy2) d2 = cal_dist(cx1,cy1,cx3,cy3) d3 = cal_dist(cx3,cy3,cx2,cy2) if((d1<=R and d2<=R) or (d1<=R and d3<=R) or (d3<=R and d2<=R)): print "yes" else: print "no" test = test-1
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math def distance(x1, y1, x2, y2): return math.sqrt((x2-x1)**2 + (y2-y1)**2) import math n = int(raw_input()) rs = [] while n != 0: max_d = int(raw_input()) p1 = map(int,raw_input().split()) p2 = map(int,raw_input().split()) p3 = map(int,raw_input().split()) ds = [] ds.append(distance(p1[0], p1[1], p2[0], p2[1])) ds.append(distance(p1[0], p1[1], p3[0], p3[1])) ds.append(distance(p2[0], p2[1], p3[0], p3[1])) ds = sorted(ds) if ds[0] <= max_d and ds[1] <= max_d: rs.append("yes") else: rs.append("no") n -= 1 for i in rs: print i
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
class Solution: def threeWayComm(self): t = int(raw_input()) while t > 0: r = int(raw_input()) if r <= 0 or r > 1000: break x1, y1 = map(int, raw_input().split()) x2, y2 = map(int, raw_input().split()) x3, y3 = map(int, raw_input().split()) if x1 > 10000 or y1 > 10000 or x2 > 10000 or y2 > 10000 or x3 > 10000 or y3 > 10000: break; count = 0 if self.isClose(x1, y1, x2, y2, r): count+=1 if self.isClose(x2, y2, x3, y3, r): count+=1 if self.isClose(x3, y3, x1, y1, r): count+=1 if count >=2: print "yes" else: print "no" t -= 1 def isClose(self, a, b, c, d, r): return (a-c)**2 + (b-d)**2 <= r**2 s = Solution() s.threeWayComm()
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from math import hypot t = input() for _ in xrange(t): r = input() x1, y1 = map(int, raw_input().split()) x2, y2 = map(int, raw_input().split()) x3, y3 = map(int, raw_input().split()) ab = hypot(x1 - x2, y1 - y2) bc = hypot(x2 - x3, y2 - y3) ac = hypot(x3 - x1, y3 - y1) if (ab <= r and bc <= r) or (ab <= r and ac <= r) or (bc <= r and ac <= r): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from math import sqrt def dist(x1,y1,x2,y2): a=(abs(x1-x2))**2 b=(abs(y1-y2))**2 return sqrt(a+b) for testcases in xrange(int(raw_input())): r=int(raw_input()) x=[] y=[] c=0 for i in xrange(3): a,b=map(int,raw_input().split()) x.append(a) y.append(b) if dist(x[0],y[0],x[1],y[1]) <= r: c+=1 if dist(x[1],y[1],x[2],y[2]) <= r: c+=1 if dist(x[0],y[0],x[2],y[2]) <= r: c+=1 if c>=2: print 'yes' else: print 'no'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math t = int(input()) l = [] while(t): r = int(input()) l = list(map(int, raw_input().split())) x1 = l[0] y1 = l[1] l = list(map(int, raw_input().split())) x2 = l[0] y2 = l[1] l = list(map(int, raw_input().split())) x3 = l[0] y3 = l[1] d1 = math.sqrt((x2 - x1) ** 2 + (y2 - y1) ** 2) d2 = math.sqrt((x3 - x2) ** 2 + (y3 - y2) ** 2) d3 = math.sqrt((x1 - x3) ** 2 + (y1 - y3) ** 2) if((d1 <= r) and (d2 <= r) and (d3 <= r)): print "yes" elif ((d1 <= r) and (d2 <= r) or (d2 <= r) and (d3 <= r) or (d3 <= r) and (d1 <= r)): print "yes" else: print "no" t -= 1
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from math import hypot T=int(raw_input()) for t in range(T): R=int(raw_input()) x1,y1=map(int,raw_input().split()) x2,y2=map(int,raw_input().split()) x3,y3=map(int,raw_input().split()) dist_1=hypot(x2-x1,y2-y1) dist_2=hypot(x3-x2,y3-y2) dist_3=hypot(x3-x1,y3-y1) if (dist_1 <=R and dist_2 <=R) or (dist_2<=R and dist_3<=R) or (dist_1<=R and dist_3<=R): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def commute(): for i in range(int(raw_input())): j =int(raw_input()) a = [] for i in range(3): a.append((map(int,raw_input().split()))) print "yes" if len([i for i in chek(a) if i<=j]) >= 2 else "no" def chek(a): return [((a[t][0] - a[(t+1)%3][0])**2 + (a[t][1] - a[(t+1)%3][1])**2)**0.5 for t in range(len(a))] commute()
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
'''input 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 ''' from math import sqrt def solve(a, b): return sqrt((a[0] - b[0]) ** 2 + (a[1] - b[1]) ** 2) for T in range(input()): d, coords = input(), [[int(i) for i in raw_input().rstrip().split()] for j in range(3)] dists = [] dists.append(solve(coords[0], coords[1])) dists.append(solve(coords[1], coords[2])) dists.append(solve(coords[2], coords[0])) print 'yes' if len(filter(lambda x: x <= d, dists)) >= 2 else 'no'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def dist(x,y,r): if ((x[0]-y[0])**2 + (x[1]-y[1])**2)**(0.5) <= r: return 1 else: return 0 t = int(raw_input()) for i in xrange(t): r = float(raw_input()) x = list() for q in xrange(3): x += [map(float,raw_input().strip().split())] isposs = 0 isposs = dist(x[0],x[1],r) + dist(x[0],x[2],r) + dist(x[1],x[2],r) print 'yes' if (isposs >= 2) else 'no'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def diff(a,b,c,d) : return float(((a-c)**2 + (b-d)**2)**0.5) for i in xrange(int(raw_input())) : k = int(raw_input().strip()) k = float(k) l = [] for j in xrange(3) : l.append(map(int,raw_input().split(' '))) diff_12 = diff(l[0][0],l[0][1],l[1][0],l[1][1]) diff_23 = diff(l[1][0],l[1][1],l[2][0],l[2][1]) diff_13 = diff(l[0][0],l[0][1],l[2][0],l[2][1]) if (diff_12 <= k) and (diff_23 <= k) : print 'yes' elif (diff_13 <= k) and (diff_23 <= k) : print 'yes' elif (diff_12 <= k) and (diff_13 <= k) : print 'yes' else : print 'no'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
# -*- coding: utf-8 -*- """ Created on Wed Jan 27 22:23:20 2016 @author: shashank """ import sys import math def distance(x,y): return math.sqrt((x[0] - y[0])**2 + (x[1] - y[1])**2) T = input() for i in range(T): R = input() chef = [int(x) for x in sys.stdin.readline().split()] head = [int(x) for x in sys.stdin.readline().split()] sous = [int(x) for x in sys.stdin.readline().split()] dist1 = distance(chef,head) dist2 = distance(chef,sous) dist3 = distance(sous,head) if ((dist1 <= R and dist2 <= R) or (dist1 <= R and dist3 <= R) or (dist2 <= R and dist3 <= R)): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def out_of_reach(xyA, xyB, reach): return ((xyB[0]-xyA[0])**2 + (xyB[1]-xyA[1])**2)**.5 > reach for tests in xrange(int(raw_input())): r = int(raw_input()) coordinates = [] for _ in range(3): coordinates.append(map(int, raw_input().split())) for pair in coordinates: t_coordinates = coordinates[:] t_coordinates.remove(pair) if len([t_pair for t_pair in t_coordinates if out_of_reach(pair, t_pair, r)]) == 2: print 'no' break else: print 'yes'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
t=int(raw_input()) for k in range(t): a=[[],[],[]] r=int(raw_input()) for j in range (3): b=map(int,raw_input().split()) a[j].append(b[0]) a[j].append(b[1]) f=0 for j in range(3): if (pow((a[j][0]-a[(j+1)%3][0]),2)+pow((a[j][1]-a[(j+1)%3][1]),2))<=(float)(r*r) and (pow((a[j][0]-a[(j+2)%3][0]),2)+pow((a[j][1]-a[(j+2)%3][1]),2))<=(float)(r*r): f=1 break; if f==1: print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
#!/usr/bin/python from math import sqrt N=input() for i in range(N): R=input() x,y=map(int,raw_input().split()) p,q=map(int,raw_input().split()) a,b=map(int,raw_input().split()) l=sqrt(((x-p)**2)+((y-q)**2)) m=sqrt(((x-a)**2)+((y-b)**2)) n=sqrt(((a-p)**2)+((b-q)**2)) #print "(%0.2f %0.2f)->(%0.2f %0.2f) = %0.2f " %(x,y,p,q,l) #print "(%0.2f %0.2f)->(%0.2f %0.2f) = %0.2f " %(x,y,a,b,m) #print "(%0.2f %0.2f)->(%0.2f %0.2f) = %0.2f " %(p,q,a,b,n) count=0 if l>R: count+=1 if m>R: count+=1 if n>R: count+=1 if count>=2: print "no" else: print "yes"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def distance(t1,t2): return ((t1[0]-t2[0])**2+(t1[1]-t2[1])**2)**0.5 t = int(input()) for test in xrange(t): r = int(input()) x1,y1 = map(int,raw_input().split()) x2,y2 = map(int,raw_input().split()) x3,y3 = map(int,raw_input().split()) dis_list = map(distance,[(x1,y1),(x1,y1),(x3,y3)],[(x2,y2),(x3,y3),(x2,y2)]) fil_list = filter(lambda x:x>r,dis_list) if len(fil_list)<2: print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def checker( pt1, pt2, R ) : dist2 = ( ( (pt1[0] - pt2[0]) **2 ) + ( (pt1[1] - pt2[1]) **2 ) ) return True if (dist2 <= (R**2)) else False for testcases in xrange(int(raw_input() ) ) : maxD = int( raw_input() ) A = map(int, raw_input().split() ) B = map(int, raw_input().split() ) C = map(int, raw_input().split() ) commList = [ checker(A, B, maxD), checker(B, C, maxD), checker(C, A, maxD) ] print 'yes' if commList.count(True) > 1 else 'no'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def is_in_range(x1, y1, x2, y2, limit): if((x1-x2)*(x1-x2)+((y1-y2)*(y1-y2)) <= limit*limit): return 1 else: return 0 tc=int(raw_input()) for _ in range(tc): limit=int(raw_input()) x1, y1=map(int, raw_input().split()) x2, y2=map(int, raw_input().split()) x3, y3=map(int, raw_input().split()) if(is_in_range(x1, y1, x2, y2,limit) + is_in_range(x1, y1, x3, y3, limit) + is_in_range(x2, y2, x3, y3, limit) > 1): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def dis(x1,y1,x2,y2): dist=(((x1-x2)**2)+((y1-y2)**2)) return dist t=int(raw_input()) while(t>0): x=0 r=int(raw_input()) chefx,chefy=raw_input().split() chefx,chefy=[int(chefx),int(chefy)] headx,heady=raw_input().split() headx,heady=[int(headx),int(heady)] sousx,sousy=raw_input().split() sousx,sousy=[int(sousx),int(sousy)] if(dis(chefx,chefy,headx,heady)<=r*r): x=x+1 if(dis(chefx,chefy,sousx,sousy)<=r*r): x=x+1 if(dis(sousx,sousy,headx,heady)<=r*r): x=x+1 if(x>1): print "yes" else: print "no" t=t-1
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import sys import math t=int(sys.stdin.readline()) for i in xrange(t): r=int(sys.stdin.readline()) a=map(int,sys.stdin.readline().split()) b=map(int,sys.stdin.readline().split()) c=map(int,sys.stdin.readline().split()) ab=math.sqrt(((b[0]-a[0])**2)+((b[1]-a[1])**2)) bc=math.sqrt(((b[0]-c[0])**2)+((b[1]-c[1])**2)) ac=math.sqrt(((c[0]-a[0])**2)+((c[1]-a[1])**2)) if ((ab<=r)&(bc<=r))|((bc<=r)&(ac<=r))|((ac<=r)&(ab<=r)): print 'yes' else: print 'no'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math def distance (a, b): return float(math.sqrt((a[0] - b[0])**2 + (a[1] - b[1])**2)) for i in range (input()): maxrange = int(input()) a = [int(j) for j in raw_input().split()] b = [int(j) for j in raw_input().split()] c = [int(j) for j in raw_input().split()] distList = [] distList.append(distance(a, b)) distList.append(distance(b, c)) distList.append(distance(a, c)) if (sum(j > maxrange for j in distList)) >= 2: print "no" else: print "yes"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
for _ in range(int(raw_input())): r=int(raw_input()) cx,cy=map(int,raw_input().split()) hsx,hsy=map(int,raw_input().split()) scx,scy=map(int,raw_input().split()) chsd = (((cx-hsx)**2)+((cy-hsy)**2))**0.5 cscd = (((cx-scx)**2)+((cy-scy)**2))**0.5 hsscd= (((scx-hsx)**2)+((scy-hsy)**2))**0.5 c=0 if chsd<=r: c+=1 if cscd<=r: c+=1 if hsscd<=r: c+=1 if c>=2: print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math t = int(raw_input()) def distance(fir,sec): val1 = int(fir[0]) - int(sec[0]) val2 = int(fir[1]) - int(sec[1]) dis = math.sqrt(val1 * val1 + val2 * val2) return dis for i in range(0,t): R = int(raw_input()) arr1 = [] arr2 = [] arr3 = [] array1 = raw_input() array2 = raw_input() array3 = raw_input() arr1 += array1.split(" ") arr2 += array2.split(" ") arr3 += array3.split(" ") res1 = distance(arr1,arr2) res2 = distance(arr2,arr3) res3 = distance(arr1,arr3) count = 0 if R >= res1 : count += 1 if R >= res2 : count += 1 if R >= res3 : count += 1 if count >= 2: print("yes") else: print("no")
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
t = int(raw_input()) t1 = [] for q in range(t): x = int(raw_input()) a = [] for i in range(3): a.append(map(int,raw_input().split())) for i in range(3): z = 0 for j in range(3): if j != i : if abs((((a[i][1]-a[j][1])**2)+((a[i][0]-a[j][0])**2))**0.5) > x : for p in range(3): if p != i and p!= j : if abs((((a[i][1]-a[p][1])**2)+((a[i][0]-a[p][0])**2))**0.5) <= x and abs((((a[j][1]-a[p][1])**2)+((a[j][0]-a[p][0])**2))**0.5) <= x : pass else : z = 1 if z == 0: t1.append("yes") else : t1.append("no") for i in range(len(t1)): print t1[i]
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def dist(p1,p2): return ((p1[0]-p2[0])**2 + (p1[1]-p2[1])**2)**0.5 x=int(raw_input()) answers=[] for i in range(x): R=int(raw_input()) p1=[0]*2 p2=[0]*2 p3=[0]*2 p1=map(int,raw_input().split()) p2=map(int,raw_input().split()) p3=map(int,raw_input().split()) d1=dist(p1,p2) d2=dist(p2,p3) d3=dist(p1,p3) if ((d1<=R and d2<=R) or (d1<R and d3<=R) or (d2<=R and d3<=R)): answers.append('yes') else: answers.append('no') for i in answers: print i
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math for _ in xrange(input()): dist = input() ax, ay = map(int, raw_input().split()) bx, by = map(int, raw_input().split()) cx, cy = map(int, raw_input().split()) l = [math.sqrt((by - ay)**2 + (bx - ax)**2), math.sqrt((cy - by)**2 + (cx - bx)**2), math.sqrt((cy - ay)**2 + (cx - ax)**2)] l1 = [c for c in l if c > dist] if len(l1) > 1: print "no" if len(l1) == 0: print "yes" else: sum1 = 0 for k in l: if k not in l1: sum1 += k if sum1 >= l1[0]: print "yes"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
#CODECHEF PROBLEM: COMM3 #AUTHOR: diksham1 t = int(raw_input()) while(t>0): range = int(raw_input()) x1,y1 = map(float, raw_input().split()) x2,y2 = map(float, raw_input().split()) x3,y3 = map(float, raw_input().split()) ctr = 0; if ((y2-y1)**2 + (x2-x1)**2)**0.5 <=range: ctr += 1; if ((y3-y1)**2 + (x3-x1)**2)**0.5 <=range: ctr += 1; if ((y2-y3)**2 + (x2-x3)**2)**0.5 <=range: ctr += 1; if ctr >=2: print "yes" else: print "no" t -= 1
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def is_in_range(x1, y1, x2, y2, limit): if((x1-x2)**2+(y1-y2)**2 <= limit**2): return 1 else: return 0 tc=int(raw_input()) for _ in range(tc): limit=int(raw_input()) x1, y1=map(int, raw_input().split()) x2, y2=map(int, raw_input().split()) x3, y3=map(int, raw_input().split()) if(is_in_range(x1, y1, x2, y2,limit) + is_in_range(x1, y1, x3, y3, limit) + is_in_range(x2, y2, x3, y3, limit) > 1): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
n=int(raw_input()) import math for _ in range(n): d=int(raw_input()) x=[int(i) for i in raw_input().strip().split(' ')] y=[int(i) for i in raw_input().strip().split(' ')] z=[int(i) for i in raw_input().strip().split(' ')] a=math.sqrt((x[0]-y[0])**2+(x[1]-y[1])**2) b=math.sqrt((x[0]-z[0])**2+(x[1]-z[1])**2) c=math.sqrt((z[0]-y[0])**2+(z[1]-y[1])**2) if (a<=d and b<=d) or (a<=d and c<=d) or (c<=d and b<=d): print 'yes' else: print 'no'
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
# @author Kilari Teja # FLOW001 for Cycle in xrange(int(raw_input().strip())): MaxRadiax = int(raw_input().strip()) Truss = False ChefOrds = [] for Chefs in xrange(0, 3): ChefOrds.append(map(int, raw_input().strip().split(" "))) for Chef in ChefOrds: Pair = 0 for Zerga in ChefOrds: PointData = ((Zerga[0] - Chef[0])**2 + (Zerga[1] - Chef[1])**2)**0.5 if PointData <= MaxRadiax and PointData != 0: Pair += 1 if Pair >= 2: print "yes" Truss = True break if not Truss: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
#Begineers Codechef 3way communication t=input() out=[] for i in range (0, t): r=input() p=[] A=raw_input() B=raw_input() C=raw_input() a=A.split() b=B.split() c=C.split() for i in range(0, 2): a[i]=int(a[i]) b[i]=int(b[i]) c[i]=int(c[i]) p.append((((a[0]-b[0])**2)+((a[1]-b[1])**2))**(0.5)) p.append((((a[0]-c[0])**2)+((a[1]-c[1])**2))**(0.5)) p.append((((c[0]-b[0])**2)+((c[1]-b[1])**2))**(0.5)) count=0 #print p[0], p[1], p[2] for i in range(0, 3): if p[i]<=r: count=count+1 #print count if count>=2.0: out.append("yes") else: out.append("no") k=0 while k<t: print out[k] k=k+1
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
T = int(raw_input()) for t in range (T): R = int(raw_input())**2 a,b = map(int,raw_input().split()) c,d = map(int,raw_input().split()) x,y = map(int,raw_input().split()) d1 = (a-c)**2 + (b-d)**2 d2 = (c-x)**2 + (d-y)**2 d3 = (a-x)**2 + (b-y)**2 if d1<=R: if d2<=R: print "yes" elif d3<=R: print "yes" else: print "no" elif d2<=R: if d3<=R: print "yes" else: print "no" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
#The Three Way Communications from math import * def dist(x1, x2, y1, y2): d = sqrt((pow((x1 - x2), 2)) + (pow((y1 - y2), 2))) return d def leng(d1, d2, d3, n): l = [d1, d2, d3] l.sort() if float(l[0]) <= n and float(l[1]) <= n and float(l[0]) + float(l[1]) >= l[2]: return True else: return False def main(): T = int(raw_input()) while(T!=0): T-=1 n = int(raw_input()) x1, y1 = raw_input().split() x2, y2 = raw_input().split() x3, y3 = raw_input().split() d1 = dist(int(x1), int(x2), int(y1), int(y2)) d2 = dist(int(x1), int(x3), int(y1), int(y3)) d3 = dist(int(x3), int(x2), int(y3), int(y2)) if leng(d1,d2,d3,n): print 'yes' else: print 'no' if __name__ == '__main__': main()
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
T = int(raw_input()) for i in range(T): R = int(raw_input()) p1 = map(int, raw_input().split()) p2 = map(int, raw_input().split()) p3 = map(int, raw_input().split()) count = 0 if ((p1[0]-p2[0])**2 + (p1[1] - p2[1])**2) > R**2: count += 1 if ((p2[0]-p3[0])**2 + (p2[1] - p3[1])**2) > R**2: count += 1 if ((p1[0]-p3[0])**2 + (p1[1] - p3[1])**2) > R**2: count += 1 print "yes" if count <= 1 else "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
t = input() while(t>0): t-=1 r = input() a=map(int,raw_input().split()) b=map(int,raw_input().split()) c=map(int,raw_input().split()) count=0 if( (a[0]-b[0])**2 +(a[1]-b[1])**2 <=r**2 ): count+=1 if( (b[0]-c[0])**2 +(c[1]-b[1])**2 <=r**2): count+=1 if( (c[0]-a[0])**2 +(c[1]-a[1])**2 <=r**2): count+=1 if(count>=2): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math T=int(raw_input()) while T>0: T-=1 R=int(raw_input()) x1,y1=map(int,raw_input().split()) x2,y2=map(int,raw_input().split()) x3,y3=map(int,raw_input().split()) dist_1=math.hypot(x2-x1,y2-y1) dist_2=math.hypot(x3-x2,y3-y2) dist_3=math.hypot(x3-x1,y3-y1) if (dist_1 <=R and dist_2 <=R) or (dist_2<=R and dist_3<=R) or (dist_1<=R and dist_3<=R): print "yes" else: print "no"
comm3
The Chef likes to stay in touch with his staff. So, the Chef, the head server, and the sous-chef all carry two-way transceivers so they can stay in constant contact. Of course, these transceivers have a limited range so if two are too far apart, they cannot communicate directly. The Chef invested in top-of-the-line transceivers which have a few advanced features. One is that even if two people cannot talk directly because they are out of range, if there is another transceiver that is close enough to both, then the two transceivers can still communicate with each other using the third transceiver as an intermediate device. There has been a minor emergency in the Chef's restaurant and he needs to communicate with both the head server and the sous-chef right away. Help the Chef determine if it is possible for all three people to communicate with each other, even if two must communicate through the third because they are too far apart. Input The first line contains a single positive integer T ≤ 100 indicating the number of test cases to follow. The first line of each test case contains a positive integer R ≤ 1,000 indicating that two transceivers can communicate directly without an intermediate transceiver if they are at most R meters away from each other. The remaining three lines of the test case describe the current locations of the Chef, the head server, and the sous-chef, respectively. Each such line contains two integers X,Y (at most 10,000 in absolute value) indicating that the respective person is located at position X,Y. Output For each test case you are to output a single line containing a single string. If it is possible for all three to communicate then you should output "yes". Otherwise, you should output "no". To be clear, we say that two transceivers are close enough to communicate directly if the length of the straight line connecting their X,Y coordinates is at most R. Example Input: 3 1 0 1 0 0 1 0 2 0 1 0 0 1 0 2 0 0 0 2 2 1 Output: yes yes no
{ "input": [ "3\n1\n0 1\n0 0\n1 0\n2\n0 1\n0 0\n1 0\n2\n0 0\n0 2\n2 1" ], "output": [ "yes\nyes\nno\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def main(): t=int(raw_input()) while t : t=t-1 r=int(raw_input()) z=[] k=[] for i in range(3): x=raw_input().split() x=map(int,x) z.append(x) r1=((z[0][0]-z[1][0])**2+(z[0][1]-z[1][1])**2)**0.5 r2=((z[1][0]-z[2][0])**2+(z[1][1]-z[2][1])**2)**0.5 r3=((z[0][0]-z[2][0])**2+(z[0][1]-z[2][1])**2)**0.5 k=[r1,r2,r3] k=sorted(k) if k[0]<=r and k[1]<=r : print "yes" else: print "no" if __name__=='__main__': main()
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): while(b): a,b=b,a%b return a t=input() while(t): a,b=map(int,raw_input().split()) print(gcd(a,b)) t=t-1;
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(a%b==0): return b; return gcd(b,a%b) t = int(raw_input()) for i in range(t): a = raw_input().split(" ") print gcd(int(a[0]),int(a[1]))
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(b==0): return a else: return gcd(b,a%b) t=input() for i in range (0,t): a,b=map(int, raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(b==0): return a else: return gcd(b,a%b) t = int(raw_input()) for i in range(t): a,b = map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): while b: a,b=b,a%b return a for i in range(int(raw_input())): a,b=map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from fractions import gcd t=input() for i in xrange(t): n1,n2=map(int,raw_input().split()) print gcd(n1,n2)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
##Using the Eucledian Method to find gcd t=input() for i in range(t): l=map(int,raw_input().split()) if l[0]>l[1]: a,b=l[0],l[1] else: a,b=l[1],l[0] while True: if b==0: print a break else: r=a%b a=b b=r
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if (b==0): return a else: return gcd(b,a%b) test = int(raw_input()) for i in range(test): a,b = map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from fractions import gcd t=input() while t: a,b=map(int,raw_input().split()) print gcd(a,b) t=t-1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b==0: return a else: return gcd(b,a%b) for i in range(int(raw_input())): a,b=map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b==0: return a else: return gcd(b,a%b) for _ in range(input()): m,n = map(int,raw_input().split()) print gcd(m,n)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(b == 0): return a else: return gcd(b,a%b) for _ in range(int(input())): a,b=map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import sys def gcd(a,b): if b == 0 : return a else: return gcd(b,a%b) try: t=int(input()) for _ in xrange(t): a,b = map(int,sys.stdin.readline().rstrip().split(' ')) print gcd(a,b) except EOFError: print("")
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from fractions import gcd for i in xrange(input()): a,b=map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a, b): if min(a,b) == 0: return max(a,b) else: if b > a: return gcd(a, b%a) else: return gcd(b, a%b) test_case = int(raw_input()) for t in range(test_case): a, b = map(int, raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
for t in xrange(int(raw_input())): a, b = map(int, raw_input().split()) while b: a, b = b, a % b print a
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b == 0: return a else: return gcd(b, a % b) t = int(raw_input()) for i in xrange(t): li = map(int, raw_input().split()) print(gcd(li[0], li[1]))
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(b==0): return a else: return gcd(b,a%b) t=(int)(input()) for i in range(t): a=map(int, raw_input().split()) print(gcd(a[0],a[1]))
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
# your code goes here def gcd(a,b): if b==0: return a else: return gcd(b,a%b) T = input() for t in xrange(T): val = raw_input().split(" ") a = long(val[0]) b = long(val[1]) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b == 0: return a else: return gcd(b,a%b) T = int(raw_input()) while T : a,b = map(int, raw_input().split()) print gcd(a,b) T -= 1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): while b: a,b=b,a%b return a t = input() while t: t=~(-t) a,b=map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b) : if b==0 : return a else : return gcd(b,a%b) t=int(input()) while t : a,b=map(int,raw_input().split()) print gcd(a,b) t-=1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(A,B): if B == 0: return A else: return gcd(B,A%B) def GCD2(): t = int(raw_input()) while t: A,B = map(int,raw_input().split()) print gcd(A,B); t-=1 if __name__ == '__main__': GCD2()
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
t=input() def gcd(a,b): if a==0: return b else: return gcd(b%a,a) for i in range(t): l=[int(x) for x in raw_input().split()] print gcd(l[0],l[1])
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(b==0): return a; else: return gcd(b,a%b) t = input() while t>0: inp = raw_input().split() a = (int)(inp[0]) b = (int)(inp[1]) ans = gcd(a,b) print ans t-=1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): while(b>0): a,b=b,a%b return a T = int(raw_input()) for i in xrange(T): a,b = map(int,raw_input().split()) print gcd(a,b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b==0: return a else: return gcd(b,a%b) t=int(input()) for i in range(0,t): p,q=raw_input().split() p=int(p) q=int(q) print gcd(p,q)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b==0: return a else: return gcd(b,a%b) t=input() while t : a,b =map(int,raw_input().split()) print(gcd(a,b)) t=t-1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd (a, b): if b == 0: return a else: return gcd (b, a % b) t=int(raw_input()) while t: a, b = map(int, raw_input().split()) print gcd(a,b) t-=1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
t = int(raw_input()) def gcd(a,b): if(b==0): return a else: return gcd(b,a%b); while(t): x = raw_input() x = x.split() a = int(x[0]) b = int(x[1]) print gcd(a,b) t = t-1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a, b): if (b==0): return a else: return gcd(b, a%b) def main(): tc=input() i=0 for i in range (0, tc): string_input=raw_input() input_list=string_input.split() input_list=[int(a) for a in input_list] print gcd(input_list[0], input_list[1]) main()
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def hcf(a,b): if b==0: return a; else: return hcf(b,a%b) for i in range(int(raw_input())): a=map(int,raw_input().split()) print hcf(a[0],a[1])
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import sys def gcd(k,m): while m!=0: r = k % m k = m m = r return k n = input() while n!=0: a, b = [int(i) for i in sys.stdin.readline().strip().split()] ans = gcd(a,b) print ans n = n-1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
from fractions import gcd st = input() for t in range(st): a, b = map(int, raw_input().split()) print gcd(a, b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a, b): if a == 0: return b else: return gcd(b % a, a) cases = int(raw_input()) for _dummy in range(cases): a, b = map(int,raw_input().split()) print gcd(a, b)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
a = input() def gcd(a,b): if b == 0: return a else: return gcd(b, a%b) for b in range(a): d = raw_input().split() print gcd(int(d[0]), int(d[1]))
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b==0: return a else: return gcd(b,a%b) ntc = int(raw_input()) while ntc!=0: a,b = map(int,raw_input().split(" ")) print gcd(a,b) ntc-=1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(x,y): while True: if y==0: return x r=x%y if r==0: return y else: x=y y=r n=input() for i in range(0,n): lis=list(raw_input().split()) n1=int(lis[0]) n2=int(lis[1]) print gcd(n2,n1)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import sys #print "AMIT" n=raw_input("") def module(a2,b2): if len(a2)<len(b2): return a2 else: c =int(a2)%int(b2) c1=str(c) return c1 def hcf(a,b): a1=a b1=b b2=b if b1=='0': print a1 return b1=module(a1,b1) hcf(b2,b1) i=0 while i<int(n): a, b = raw_input("").split() #tokenizedInput = sys.stdin.read().split() #a, b = map(str, tokenizedInput[:2]) hcf(a,b) i=i+1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(b==0): return a else: return gcd(b,a%b) cases=int(raw_input()) for i in range(cases): a,b=map(str,raw_input().split()) a=int(a); ans=0; if a==0: print b else: for i in b: ans=(ans*10 + int(i))%a print gcd(a,ans)
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import sys def GCD(A,B): if B==0: return A else: return GCD(B, A%B) n= int(input()) while n>0: A,B= map(int, sys.stdin.readline().split()) print GCD(A,B) n-= 1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(at,bt): if(bt==0): return at; else: return gcd(bt,at%bt) t = input() # main while t>0: inp = raw_input().split() a = (int)(inp[0]) b = (int)(inp[1]) ans = gcd(a,b) print ans t-=1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if(b==0): return a else: return gcd(b,a%b) def main(): t=input() t1=t lt=[] while(t>0): a,b=raw_input().split() a,b=int(a),int(b) x=gcd(a,b) lt.append(x) t=t-1 #print lt for i in range(t1): print lt[i] if __name__ == '__main__': main()
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
# cook your code here def getModuloOf(a, two): i=1; b = int(two[:i]); while(b<a and i<len(two)): i=i+1; b=int(two[:i]); if(b<a or i==len(two)): return b%a; else: rem=b%a; s=str(rem)+two[i:]; return getModuloOf(a,s); def findHCF(a, b): if(a==0): return b; return findHCF(b%a,a); t=int(raw_input()); #waste=raw_input(); while(t>0): a,two = raw_input().split(' '); a=int(a); if(a==0): print two; else: b=getModuloOf(a,two); ans=findHCF(b,a); print ans; t=t-1;
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a,b): if b==0: return a else: return gcd(b,a%b) t=input() while t>0: a,b = map(int, raw_input().split(" ")) print gcd(a,b) t-=1
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def gcd(a, b): if(a == 0): return b; return gcd(b % a, a); t = input(); while(t > 0): a, b = map(int, raw_input().split()); print gcd(a, b); t -= 1;
gcd2
Frank explained its friend Felman the algorithm of Euclides to calculate the GCD of two numbers. Then Felman implements it algorithm int gcd(int a, int b) { if (b==0) return a; else return gcd(b,a%b); } and it proposes to Frank that makes it but with a little integer and another integer that has up to 250 digits. Your task is to help Frank programming an efficient code for the challenge of Felman. Input The first line of the input file contains a number representing the number of lines to follow. Each line consists of two number A and B (0 ≤ A ≤ 40000 and A ≤ B < 10^250). Output Print for each pair (A,B) in the input one integer representing the GCD of A and B. Example Input: 2 2 6 10 11 Output: 2 1
{ "input": [ "2\n2 6\n10 11" ], "output": [ "2\n1\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
import math import sys def parseIntList(str): return [long(x) for x in str.split()] def printBS(li): if len(li) is 0: print else: for i in range(len(li)-1): print li[i], print li[-1] def gcd(a,b): if b==0: return a return gcd(b,a%b) cases=input() for case in range(cases): b,a=raw_input().split() b=int(b) if b==0: print a else: num=0 for i in a: num=(num*10+int(i))%b print gcd(b,num)
luckybal
A Little Elephant from the Zoo of Lviv likes lucky strings, i.e., the strings that consist only of the lucky digits 4 and 7. The Little Elephant calls some string T of the length M balanced if there exists at least one integer X (1 ≤ X ≤ M) such that the number of digits 4 in the substring T[1, X - 1] is equal to the number of digits 7 in the substring T[X, M]. For example, the string S = 7477447 is balanced since S[1, 4] = 7477 has 1 digit 4 and S[5, 7] = 447 has 1 digit 7. On the other hand, one can verify that the string S = 7 is not balanced. The Little Elephant has the string S of the length N. He wants to know the number of such pairs of integers (L; R) that 1 ≤ L ≤ R ≤ N and the substring S[L, R] is balanced. Help him to find this number. Notes. Let S be some lucky string. Then |S| denotes the length of the string S; S[i] (1 ≤ i ≤ |S|) denotes the i^th character of S (the numeration of characters starts from 1); S[L, R] (1 ≤ L ≤ R ≤ |S|) denotes the string with the following sequence of characters: S[L], S[L + 1], ..., S[R], and is called a substring of S. For L > R we mean by S[L, R] an empty string. Input The first line of the input file contains a single integer T, the number of test cases. Each of the following T lines contains one string, the string S for the corresponding test case. The input file does not contain any whitespaces. Output For each test case output a single line containing the answer for this test case. Constraints 1 ≤ T ≤ 10 1 ≤ |S| ≤ 100000 S consists only of the lucky digits 4 and 7. Example Input: 4 47 74 477 4747477 Output: 2 2 3 23 Explanation In the first test case balance substrings are S[1, 1] = 4 and S[1, 2] = 47. In the second test case balance substrings are S[2, 2] = 4 and S[1, 2] = 74. Unfortunately, we can't provide you with the explanations of the third and the fourth test cases. You should figure it out by yourself. Please, don't ask about this in comments.
{ "input": [ "4\n47\n74\n477\n4747477" ], "output": [ "2\n2\n3\n23\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
n = input() for i in range(n): str = raw_input() l = len(str) megacounter = 0 counter = 0 i = 0 while(1): while(i<l and str[i]=='7'): i=i+1 counter=counter+1 if(i>=l): break megacounter = megacounter + (counter*(counter+1))/2 i=i+1 counter=0 megacounter = megacounter + (counter*(counter+1))/2 supercounter = (l*(l+1))/2 - megacounter print supercounter
luckybal
A Little Elephant from the Zoo of Lviv likes lucky strings, i.e., the strings that consist only of the lucky digits 4 and 7. The Little Elephant calls some string T of the length M balanced if there exists at least one integer X (1 ≤ X ≤ M) such that the number of digits 4 in the substring T[1, X - 1] is equal to the number of digits 7 in the substring T[X, M]. For example, the string S = 7477447 is balanced since S[1, 4] = 7477 has 1 digit 4 and S[5, 7] = 447 has 1 digit 7. On the other hand, one can verify that the string S = 7 is not balanced. The Little Elephant has the string S of the length N. He wants to know the number of such pairs of integers (L; R) that 1 ≤ L ≤ R ≤ N and the substring S[L, R] is balanced. Help him to find this number. Notes. Let S be some lucky string. Then |S| denotes the length of the string S; S[i] (1 ≤ i ≤ |S|) denotes the i^th character of S (the numeration of characters starts from 1); S[L, R] (1 ≤ L ≤ R ≤ |S|) denotes the string with the following sequence of characters: S[L], S[L + 1], ..., S[R], and is called a substring of S. For L > R we mean by S[L, R] an empty string. Input The first line of the input file contains a single integer T, the number of test cases. Each of the following T lines contains one string, the string S for the corresponding test case. The input file does not contain any whitespaces. Output For each test case output a single line containing the answer for this test case. Constraints 1 ≤ T ≤ 10 1 ≤ |S| ≤ 100000 S consists only of the lucky digits 4 and 7. Example Input: 4 47 74 477 4747477 Output: 2 2 3 23 Explanation In the first test case balance substrings are S[1, 1] = 4 and S[1, 2] = 47. In the second test case balance substrings are S[2, 2] = 4 and S[1, 2] = 74. Unfortunately, we can't provide you with the explanations of the third and the fourth test cases. You should figure it out by yourself. Please, don't ask about this in comments.
{ "input": [ "4\n47\n74\n477\n4747477" ], "output": [ "2\n2\n3\n23\n" ] }
{ "input": [], "output": [] }
CORRECT
python2
def calc(str): length = len(str) prev_four = -1 count = 0 for i in range(0,length): if str[i] == "4": count+=(i-prev_four)*(length-i) prev_four = i return count t = int(raw_input()) for i in range(0,t): str = raw_input() print calc(str)
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