def runTests(sampleNum, a, b):
runs = []
for ii in xrange(sampleNum):
out = []
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
out.append(timing.dotest(lambda: a + b))
out.append(timing.dotest(lambda: ra + rb))
out.append(timing.dotest(lambda: a - b))
out.append(timing.dotest(lambda: ra - rb))
out.append(timing.dotest(lambda: a * b))
out.append(timing.dotest(lambda: ra * rb))
if (b != 0):
out.append(timing.dotest(lambda: a / b))
out.append(timing.dotest(lambda: ra / rb))
out.append(timing.dotest(lambda: a % b))
out.append(timing.dotest(lambda: ra % rb))
else:
out.extend([0, 0, 0, 0])
runs.append(out)
base = runs.pop(0)
for run in runs:
for ii in xrange(len(base)):
base[ii] += run[ii]
for ii in xrange(len(base)):
base[ii] /= (1.0 * sampleNum)
return base
def stressTest():
count = 0
product = 0
sparseAns = 0
rand1 = random.randint(0, 10000000000)
rand2 = random.randint(0, 10000000000)
if (rand2 > rand2):
temp = rand2
rand2 = rand1
rand1 = temp
productNorm = rand1 * rand2
sumNorm = rand1 + rand2
diffNorm = rand1 - rand2
quotNorm = rand1 / rand2
modNorm = rand1 % rand2
a = rrrsparse.RRRSparse(rand1)
b = rrrsparse.RRRSparse(rand2)
if (int(a + b) != sumNorm):
print "Failed on " + str(rand1) + " + " + str(rand2)
return False
#if(int(a*b)!=productNorm):
# print "Failed on "+ str(rand1) + " * " + str(rand2)
# return False
#if(int(a-b)!=diffNorm):
# print "Failed on "+ str(rand1) + " - " + str(rand2)
# return False
#if(int(a/b)!=quotNorm):
# print "Failed on "+ str(rand1) + " / " + str(rand2)
# return False
#if(int(a%b)!=modNorm):
# print "Failed on "+ str(rand1) + " % " + str(rand2)
# return False
return True
def doMath(a, b, c):
# get the correct answers
if (c == 0):
c = 1
powModNorm = a**b % c
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
rc = rrrsparse.RRRSparse(c)
result = rrrsparse.RRRSparse()
result = result.powMod(ra, rb, rc)
if (result != powModNorm):
print "Pow Mod Failed"
print "Sparse gave " + str(int(result))
print "Normal math gave " + str(powModNorm)
return False
return True
def runTests(sampleNum, a, b):
out = []
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
out.append(timing.dotest(lambda: a + b))
out.append(timing.dotest(lambda: ra + rb))
out.append(timing.dotest(lambda: a - b))
out.append(timing.dotest(lambda: ra - rb))
out.append(timing.dotest(lambda: a * b))
out.append(timing.dotest(lambda: ra * rb))
if (b != 0):
out.append(timing.dotest(lambda: a / b))
out.append(timing.dotest(lambda: ra / rb))
out.append(timing.dotest(lambda: a % b))
out.append(timing.dotest(lambda: ra % rb))
else:
out.extend([0, 0, 0, 0])
return out
def getTimes(sampleNum, a, b):
test = []
for ii in xrange(max(sampleNum, 1)):
out = []
t1 = datetime.datetime.now()
z = a + b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = a - b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = a * b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
if (b != 0):
t1 = datetime.datetime.now()
z = a / b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
else:
out.append(0)
if (b != 0):
t1 = datetime.datetime.now()
z = a % b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
else:
out.append(0)
t1 = datetime.datetime.now()
z = a == b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = a < b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = a <= b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = a != b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = a > b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = a >= b
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
t1 = datetime.datetime.now()
z = -a
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra + rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra - rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra * rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
if b != 0:
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra / rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
else:
out.append(0)
if b != 0:
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra % rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
else:
out.append(0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra == rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra < rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra <= rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra != rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra > rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = ra >= rb
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
t1 = datetime.datetime.now()
z = -ra
t2 = datetime.datetime.now()
c = t1 - t2
out.append(c.seconds + c.microseconds / 1000000.0)
test.append(out)
result = []
for ii in xrange(len(test[-1])):
result.append(0)
for jj in xrange(len(test)):
result[-1] += test[jj][ii]
result[-1] /= (len(test) * 1.0)
return result
import rrrsparse x = rrrsparse.RRRSparse(2) y = rrrsparse.RRRSparse(1) print int(y - x) z = y - x print z.digits print y - x print int(z)
def doMath(a, b):
# get the correct answers
normSum = a + b
normDiff = a - b
normMult = a * b
normNe = a != b
normEq = a == b
normLt = a < b
normLte = a <= b
normGt = a > b
normGte = a >= b
if (b != 0):
normDiv = a // b
if (b != 0):
normMod = a % b
# first test sparse int
"""asp = sparseInt.SparseInt(a)
bsp = sparseInt.SparseInt(b)
if(asp + bsp != normSum):
print "Sum Failed"
return False
if(asp - bsp != normDiff):
print "Difference Failed"
return False
if(asp * bsp != normMult):
print "Normal Multiplication Failed"
return False
if(b>0):
if(asp / bsp != normDiv):
print "Division Failed"
return False
if(asp % bsp != normMod):
print "Modulus Failed"
return False
if(sparseInt(heapMult.HeapMult.sparseHeapMult(asp.digits,bsp.digits))!=
normMult):
print "Heap Mult Failed"
return False"""
# Now Test the sparse rrr
ra = rrrsparse.RRRSparse(a)
rb = rrrsparse.RRRSparse(b)
if (ra + rb != normSum):
print "RRR Sum Failed"
return False
#ra = rrrsparse.RRRSparse(a)
#rb = rrrsparse.RRRSparse(b)
if (ra - rb != normDiff):
print "RRR Sub Failed"
#print "had " +str(int(ra -rb)) + " when it needed "+str(normDiff)
return False
#ra = rrrsparse.RRRSparse(a)
#rb = rrrsparse.RRRSparse(b)
if (ra * rb != normMult):
print "RRR Mult Failed"
return False
#ra = rrrsparse.RRRSparse(a)
#rb = rrrsparse.RRRSparse(b)
if b != 0:
#ra = rrrsparse.RRRSparse(a)
#rb = rrrsparse.RRRSparse(b)
# print (ra / rb).digits
product = ra / rb
if (product != normDiv):
print "RRR Div Failed"
print "Normal Math gave " + str(normDiv)
print "Sparse Math gave " + str(product)
return False
#ra = rrrsparse.RRRSparse(a)
#rb = rrrsparse.RRRSparse(b)
if (b != 0 and b > 0 and a > 0):
temp = ra % rb
if (temp != normMod):
print "RRR mod failed"
print "Sparse gave " + str(int(temp))
print "Real Math gave " + str(normMod)
return False
#return True"""
# boolean section
#ra = rrrsparse.RRRSparse(a)
#rb = rrrsparse.RRRSparse(b)
if (ra != rb) != normNe:
print "RRR Not Equal failed"
return False
if (ra == rb) != normEq:
print "RRR Equal failed"
return False
if (ra < rb) != normLt:
print "RRR Less Than failed"
return False
if (ra <= rb) != normLte:
print "RRR Less Than or Equal failed"
return False
if (ra > rb) != normGt:
print "RRR Greaer failed"
return False
if (ra >= rb) != normGte:
print "RRR Greater Than or Equal failed"
return False
return True
outStr += "1"
sn = d[p][0] < 1
p += 1
else:
if sn:
outStr += "1"
else:
outStr += "0"
if (outStr[-1] == "0"):
return outStr[:len(outStr) - 1]
return outStr
#print "decimal\tsparse\nbinary reversed"
num = 0
while (True):
spnum = rrrsparse.RRRSparse(num)
if (bin(num).split('b')[1][::-1] != simple(spnum)):
outStr = str(num) + "\t"
spnum = rrrsparse.RRRSparse(num)
outStr += spnum.oldStr() + "\t"
outStr += bin(num).split('b')[1][::-1]
print outStr + "\tfliped binary"
outStr = str(num) + "\t"
spnum = rrrsparse.RRRSparse(num)
outStr += spnum.oldStr() + "\t"
outStr += simple(spnum)
print outStr + "\tcalculated"
break
num += 1
