interstar/scope.py

## scope.py
print("""
# Scope demo in Python

# the x bound in the scope of f is visible within y
# but is not the same as the x bound at the global scope

x = 4
y = 3
def f(x) :
    def g(y) :
        print("in g, x is %s" % x)
        print("in g, y is %s" % y)
        return x * y
    print("in f, x is %s" % x)
    return g


print("global x is %s, y is %s"%(x,y))
print("calculating .... the result is %s "% f(5)(6))
print("global x is %s, y is %s"%(x,y))

>>>
""")

x = 4
y = 3
def f(x) :
    def g(y) :
        print("in g, x is %s" % x)
        print("in g, y is %s" % y)
        return x * y
    print("in f, x is %s" % x)
    return g


print("global x is %s, y is %s"%(x,y))
print("calculating .... the result is %s "% f(5)(6))
print("global x is %s, y is %s"%(x,y))

print("""

# what you can't do in python is assign to the captured variable x inside function g
# that will give an error

# there isn't an explicit "upvar" but as a workaround you can use global,
# but that means something different, and makes you work with global vars,
# which isn't ideal

# So it's best to treat variables captured in closures as immutable

# which is actually a good thing anyway, because updating them
# can lead to a world of confusion and pain

# If you REALLY want mutable variables in a context which can be passed around
# It's better to just use a class and do things the Object Oriented way
# which is more explicit and easy for people to understand

class F :
    def __init__(self,x) :
        self.x = x
        print("in F, x is %s" % self.x)

    def updateX(self,x) :
        self.x = x
        print("in F, x is now %s" % self.x)
        return self

    def calcWithY(self,y) :
        print("in calc, x is %s" % self.x)
        print("in calc, y is %s" % y)
        return self.x * y


print("oo result is %s " % F(9).updateX(5).calcWithY(6))
print("global x is %s, y is %s"%(x,y))

>>>
""")

class F :
    def __init__(self,x) :
        self.x = x
        print("in F, x is %s" % self.x)

    def updateX(self,x) :
        self.x = x
        print("in F, x is now %s" % self.x)
        return self

    def calcWithY(self,y) :
        print("in calc, x is %s" % self.x)
        print("in calc, y is %s" % y)
        return self.x * y


print("oo result is %s " % F(9).updateX(5).calcWithY(6))
print("global x is %s, y is %s"%(x,y))

print("""
# Python makes a good trade-off here, I think
# Closures are more concise and arguably more expressive
# But less explicit and so somewhat harder to understand

# Immutability makes things easier to understand

# So immutable captured variables in closures buys
# ease of understanding at the cost of reduced power

# And if you really need mutability, python forces you to use OO

# Which makes things more explicit and familiar
# particularly because of Python's self notation
# You can't confuse self.x with any x's that are floating around the global namespace
""")
	print("""
	# Scope demo in Python

	# the x bound in the scope of f is visible within y
	# but is not the same as the x bound at the global scope

	x = 4
	y = 3
	def f(x) :
	def g(y) :
	print("in g, x is %s" % x)
	print("in g, y is %s" % y)
	return x * y
	print("in f, x is %s" % x)
	return g


	print("global x is %s, y is %s"%(x,y))
	print("calculating .... the result is %s "% f(5)(6))
	print("global x is %s, y is %s"%(x,y))

	>>>
	""")

	x = 4
	y = 3
	def f(x) :
	def g(y) :
	print("in g, x is %s" % x)
	print("in g, y is %s" % y)
	return x * y
	print("in f, x is %s" % x)
	return g


	print("global x is %s, y is %s"%(x,y))
	print("calculating .... the result is %s "% f(5)(6))
	print("global x is %s, y is %s"%(x,y))

	print("""

	# what you can't do in python is assign to the captured variable x inside function g
	# that will give an error

	# there isn't an explicit "upvar" but as a workaround you can use global,
	# but that means something different, and makes you work with global vars,
	# which isn't ideal

	# So it's best to treat variables captured in closures as immutable

	# which is actually a good thing anyway, because updating them
	# can lead to a world of confusion and pain

	# If you REALLY want mutable variables in a context which can be passed around
	# It's better to just use a class and do things the Object Oriented way
	# which is more explicit and easy for people to understand

	class F :
	def __init__(self,x) :
	self.x = x
	print("in F, x is %s" % self.x)

	def updateX(self,x) :
	self.x = x
	print("in F, x is now %s" % self.x)
	return self

	def calcWithY(self,y) :
	print("in calc, x is %s" % self.x)
	print("in calc, y is %s" % y)
	return self.x * y


	print("oo result is %s " % F(9).updateX(5).calcWithY(6))
	print("global x is %s, y is %s"%(x,y))

	>>>
	""")

	class F :
	def __init__(self,x) :
	self.x = x
	print("in F, x is %s" % self.x)

	def updateX(self,x) :
	self.x = x
	print("in F, x is now %s" % self.x)
	return self

	def calcWithY(self,y) :
	print("in calc, x is %s" % self.x)
	print("in calc, y is %s" % y)
	return self.x * y


	print("oo result is %s " % F(9).updateX(5).calcWithY(6))
	print("global x is %s, y is %s"%(x,y))

	print("""
	# Python makes a good trade-off here, I think
	# Closures are more concise and arguably more expressive
	# But less explicit and so somewhat harder to understand

	# Immutability makes things easier to understand

	# So immutable captured variables in closures buys
	# ease of understanding at the cost of reduced power

	# And if you really need mutability, python forces you to use OO

	# Which makes things more explicit and familiar
	# particularly because of Python's self notation
	# You can't confuse self.x with any x's that are floating around the global namespace
	""")