Modules/_decimal/tests/bench.py - platform/external/python/cpython3 - Gitiles

 #
 # Copyright (C) 2001-2012 Python Software Foundation. All Rights Reserved.
 # Modified and extended by Stefan Krah.
 #

 # Usage: ../../../python bench.py


 import time
 from math import log, ceil
 try:
     from test.support import import_fresh_module
 except ImportError:
     from test.test_support import import_fresh_module

 C = import_fresh_module('decimal', fresh=['_decimal'])
 P = import_fresh_module('decimal', blocked=['_decimal'])

 #
 # NOTE: This is the pi function from the decimal documentation, modified
 # for benchmarking purposes. Since floats do not have a context, the higher
 # intermediate precision from the original is NOT used, so the modified
 # algorithm only gives an approximation to the correctly rounded result.
 # For serious use, refer to the documentation or the appropriate literature.
 #
 def pi_float():
     """native float"""
     lasts, t, s, n, na, d, da = 0, 3.0, 3, 1, 0, 0, 24
     while s != lasts:
         lasts = s
         n, na = n+na, na+8
         d, da = d+da, da+32
         t = (t * n) / d
         s += t
     return s

 def pi_cdecimal():
     """cdecimal"""
     D = C.Decimal
     lasts, t, s, n, na, d, da = D(0), D(3), D(3), D(1), D(0), D(0), D(24)
     while s != lasts:
         lasts = s
         n, na = n+na, na+8
         d, da = d+da, da+32
         t = (t * n) / d
         s += t
     return s

 def pi_decimal():
     """decimal"""
     D = P.Decimal
     lasts, t, s, n, na, d, da = D(0), D(3), D(3), D(1), D(0), D(0), D(24)
     while s != lasts:
         lasts = s
         n, na = n+na, na+8
         d, da = d+da, da+32
         t = (t * n) / d
         s += t
     return s

 def factorial(n, m):
     if (n > m):
         return factorial(m, n)
     elif m == 0:
         return 1
     elif n == m:
         return n
     else:
         return factorial(n, (n+m)//2) * factorial((n+m)//2 + 1, m)


 print("\n# ======================================================================")
 print("#                   Calculating pi, 10000 iterations")
 print("# ======================================================================\n")

 to_benchmark = [pi_float, pi_decimal]
 if C is not None:
     to_benchmark.insert(1, pi_cdecimal)

 for prec in [9, 19]:
     print("\nPrecision: %d decimal digits\n" % prec)
     for func in to_benchmark:
         start = time.time()
         if C is not None:
             C.getcontext().prec = prec
         P.getcontext().prec = prec
         for i in range(10000):
             x = func()
         print("%s:" % func.__name__.replace("pi_", ""))
         print("result: %s" % str(x))
         print("time: %fs\n" % (time.time()-start))


 print("\n# ======================================================================")
 print("#                               Factorial")
 print("# ======================================================================\n")

 if C is not None:
     c = C.getcontext()
     c.prec = C.MAX_PREC
     c.Emax = C.MAX_EMAX
     c.Emin = C.MIN_EMIN

 for n in [100000, 1000000]:

     print("n = %d\n" % n)

     if C is not None:
         # C version of decimal
         start_calc = time.time()
         x = factorial(C.Decimal(n), 0)
         end_calc = time.time()
         start_conv = time.time()
         sx = str(x)
         end_conv = time.time()
         print("cdecimal:")
         print("calculation time: %fs" % (end_calc-start_calc))
         print("conversion time: %fs\n" % (end_conv-start_conv))

     # Python integers
     start_calc = time.time()
     y = factorial(n, 0)
     end_calc = time.time()
     start_conv = time.time()
     sy = str(y)
     end_conv =  time.time()

     print("int:")
     print("calculation time: %fs" % (end_calc-start_calc))
     print("conversion time: %fs\n\n" % (end_conv-start_conv))

     if C is not None:
         assert(sx == sy)
	#
	# Copyright (C) 2001-2012 Python Software Foundation. All Rights Reserved.
	# Modified and extended by Stefan Krah.
	#

	# Usage: ../../../python bench.py


	import time
	from math import log, ceil
	try:
	from test.support import import_fresh_module
	except ImportError:
	from test.test_support import import_fresh_module

	C = import_fresh_module('decimal', fresh=['_decimal'])
	P = import_fresh_module('decimal', blocked=['_decimal'])

	#
	# NOTE: This is the pi function from the decimal documentation, modified
	# for benchmarking purposes. Since floats do not have a context, the higher
	# intermediate precision from the original is NOT used, so the modified
	# algorithm only gives an approximation to the correctly rounded result.
	# For serious use, refer to the documentation or the appropriate literature.
	#
	def pi_float():
	"""native float"""
	lasts, t, s, n, na, d, da = 0, 3.0, 3, 1, 0, 0, 24
	while s != lasts:
	lasts = s
	n, na = n+na, na+8
	d, da = d+da, da+32
	t = (t * n) / d
	s += t
	return s

	def pi_cdecimal():
	"""cdecimal"""
	D = C.Decimal
	lasts, t, s, n, na, d, da = D(0), D(3), D(3), D(1), D(0), D(0), D(24)
	while s != lasts:
	lasts = s
	n, na = n+na, na+8
	d, da = d+da, da+32
	t = (t * n) / d
	s += t
	return s

	def pi_decimal():
	"""decimal"""
	D = P.Decimal
	lasts, t, s, n, na, d, da = D(0), D(3), D(3), D(1), D(0), D(0), D(24)
	while s != lasts:
	lasts = s
	n, na = n+na, na+8
	d, da = d+da, da+32
	t = (t * n) / d
	s += t
	return s

	def factorial(n, m):
	if (n > m):
	return factorial(m, n)
	elif m == 0:
	return 1
	elif n == m:
	return n
	else:
	return factorial(n, (n+m)//2) * factorial((n+m)//2 + 1, m)


	print("\n# ======================================================================")
	print("# Calculating pi, 10000 iterations")
	print("# ======================================================================\n")

	to_benchmark = [pi_float, pi_decimal]
	if C is not None:
	to_benchmark.insert(1, pi_cdecimal)

	for prec in [9, 19]:
	print("\nPrecision: %d decimal digits\n" % prec)
	for func in to_benchmark:
	start = time.time()
	if C is not None:
	C.getcontext().prec = prec
	P.getcontext().prec = prec
	for i in range(10000):
	x = func()
	print("%s:" % func.__name__.replace("pi_", ""))
	print("result: %s" % str(x))
	print("time: %fs\n" % (time.time()-start))


	print("\n# ======================================================================")
	print("# Factorial")
	print("# ======================================================================\n")

	if C is not None:
	c = C.getcontext()
	c.prec = C.MAX_PREC
	c.Emax = C.MAX_EMAX
	c.Emin = C.MIN_EMIN

	for n in [100000, 1000000]:

	print("n = %d\n" % n)

	if C is not None:
	# C version of decimal
	start_calc = time.time()
	x = factorial(C.Decimal(n), 0)
	end_calc = time.time()
	start_conv = time.time()
	sx = str(x)
	end_conv = time.time()
	print("cdecimal:")
	print("calculation time: %fs" % (end_calc-start_calc))
	print("conversion time: %fs\n" % (end_conv-start_conv))

	# Python integers
	start_calc = time.time()
	y = factorial(n, 0)
	end_calc = time.time()
	start_conv = time.time()
	sy = str(y)
	end_conv = time.time()

	print("int:")
	print("calculation time: %fs" % (end_calc-start_calc))
	print("conversion time: %fs\n\n" % (end_conv-start_conv))

	if C is not None:
	assert(sx == sy)