cpython/Lib/test/test_scope.py

from test.test_support import verify, TestFailed

print "1. simple nesting"

def make_adder(x):
    def adder(y):
        return x + y
    return adder

inc = make_adder(1)
plus10 = make_adder(10)

verify(inc(1) == 2)
verify(plus10(-2) == 8)

print "2. extra nesting"

def make_adder2(x):
    def extra(): # check freevars passing through non-use scopes
        def adder(y):
            return x + y
        return adder
    return extra()

inc = make_adder2(1)
plus10 = make_adder2(10)

verify(inc(1) == 2)
verify(plus10(-2) == 8)

print "3. simple nesting + rebinding"

def make_adder3(x):
    def adder(y):
        return x + y
    x = x + 1 # check tracking of assignment to x in defining scope
    return adder

inc = make_adder3(0)
plus10 = make_adder3(9)

verify(inc(1) == 2)
verify(plus10(-2) == 8)

print "4. nesting with global but no free"

def make_adder4(): # XXX add exta level of indirection
    def nest():
        def nest():
            def adder(y):
                return global_x + y # check that plain old globals work
            return adder
        return nest()
    return nest()

global_x = 1
adder = make_adder4()
verify(adder(1) == 2)

global_x = 10
verify(adder(-2) == 8)

print "5. nesting through class"

def make_adder5(x):
    class Adder:
        def __call__(self, y):
            return x + y
    return Adder()

inc = make_adder5(1)
plus10 = make_adder5(10)

verify(inc(1) == 2)
verify(plus10(-2) == 8)

print "6. nesting plus free ref to global"

def make_adder6(x):
    global global_nest_x
    def adder(y):
        return global_nest_x + y
    global_nest_x = x
    return adder

inc = make_adder6(1)
plus10 = make_adder6(10)

verify(inc(1) == 11) # there's only one global
verify(plus10(-2) == 8)

print "7. nearest enclosing scope"

def f(x):
    def g(y):
        x = 42 # check that this masks binding in f()
        def h(z):
            return x + z
        return h
    return g(2)

test_func = f(10)
verify(test_func(5) == 47)

print "8. mixed freevars and cellvars"

def identity(x):
    return x

def f(x, y, z):
    def g(a, b, c):
        a = a + x # 3
        def h():
            # z * (4 + 9)
            # 3 * 13
            return identity(z * (b + y))
        y = c + z # 9
        return h
    return g

g = f(1, 2, 3)
h = g(2, 4, 6)
verify(h() == 39)

print "9. free variable in method"

def test():
    method_and_var = "var"
    class Test:
        def method_and_var(self):
            return "method"
        def test(self):
            return method_and_var
        def actual_global(self):
            return str("global")
        def str(self):
            return str(self)
    return Test()

t = test()
verify(t.test() == "var")
verify(t.method_and_var() == "method")
verify(t.actual_global() == "global")

method_and_var = "var"
class Test:
    # this class is not nested, so the rules are different
    def method_and_var(self):
        return "method"
    def test(self):
        return method_and_var
    def actual_global(self):
        return str("global")
    def str(self):
        return str(self)

t = Test()
verify(t.test() == "var")
verify(t.method_and_var() == "method")
verify(t.actual_global() == "global")

print "10. recursion"

def f(x):
    def fact(n):
        if n == 0:
            return 1
        else:
            return n * fact(n - 1)
    if x >= 0:
        return fact(x)
    else:
        raise ValueError, "x must be >= 0"

verify(f(6) == 720)


print "11. unoptimized namespaces"

def check_syntax(s):
    try:
        compile(s, '?', 'exec')
    except SyntaxError:
        pass
    else:
        raise TestFailed

# XXX for now, it is easiest to call this a syntax error:
# explicit is better than implicit...
test1 = \
"""def unoptimized_clash1(strip):
    def f(s):
        from string import *
        return strip(s) # ambiguity: free or local
    return f
"""
check_syntax(test1)

# a little harder to reject this one, but possible...
test2 = \
"""def unoptimized_clash2():
    from string import *
    def f(s):
        return strip(s) # ambiguity: global or local
    return f
"""
# check_syntax(test2)

# XXX could allow this for exec with const argument, but what's the point
test3 = \
"""def error(y):
    exec "a = 1"
    def f(x):
        return x + y
    return f
"""
check_syntax(test3)

test4 = \
"""def f(x):
    def g():
        return x
    del x
"""
check_syntax(test4)

print "12. lambdas"

f1 = lambda x: lambda y: x + y
inc = f1(1)
plus10 = f1(10)
verify(inc(1) == 2)
verify(plus10(5) == 15)

f2 = lambda x: (lambda : lambda y: x + y)()
inc = f2(1)
plus10 = f2(10)
verify(inc(1) == 2)
verify(plus10(5) == 15)

f3 = lambda x: lambda y: global_x + y
global_x = 1
inc = f3(None)
verify(inc(2) == 3)

f8 = lambda x, y, z: lambda a, b, c: lambda : z * (b + y)
g = f8(1, 2, 3)
h = g(2, 4, 6)
verify(h() == 18)

print "13. UnboundLocal"

def errorInOuter():
    print y
    def inner():
        return y
    y = 1

def errorInInner():
    def inner():
        return y
    inner()
    y = 1

try:
    errorInOuter()
except UnboundLocalError:
    pass
else:
    raise TestFailed

try:
    errorInInner()
except UnboundLocalError:
    pass
else:
    raise TestFailed
PEP 227 implementation New tests cases for nested scopes. 2001-01-25 16:11:23 -04:00			`from test.test_support import verify, TestFailed`

			`print "1. simple nesting"`

			`def make_adder(x):`
			`def adder(y):`
			`return x + y`
			`return adder`

			`inc = make_adder(1)`
			`plus10 = make_adder(10)`

			`verify(inc(1) == 2)`
			`verify(plus10(-2) == 8)`

			`print "2. extra nesting"`

			`def make_adder2(x):`
			`def extra(): # check freevars passing through non-use scopes`
			`def adder(y):`
			`return x + y`
			`return adder`
			`return extra()`

			`inc = make_adder2(1)`
			`plus10 = make_adder2(10)`

			`verify(inc(1) == 2)`
			`verify(plus10(-2) == 8)`

			`print "3. simple nesting + rebinding"`

			`def make_adder3(x):`
			`def adder(y):`
			`return x + y`
			`x = x + 1 # check tracking of assignment to x in defining scope`
			`return adder`

			`inc = make_adder3(0)`
			`plus10 = make_adder3(9)`

			`verify(inc(1) == 2)`
			`verify(plus10(-2) == 8)`

			`print "4. nesting with global but no free"`

			`def make_adder4(): # XXX add exta level of indirection`
			`def nest():`
			`def nest():`
			`def adder(y):`
			`return global_x + y # check that plain old globals work`
			`return adder`
			`return nest()`
			`return nest()`

			`global_x = 1`
			`adder = make_adder4()`
			`verify(adder(1) == 2)`

			`global_x = 10`
			`verify(adder(-2) == 8)`

			`print "5. nesting through class"`

			`def make_adder5(x):`
			`class Adder:`
			`def __call__(self, y):`
			`return x + y`
			`return Adder()`

			`inc = make_adder5(1)`
			`plus10 = make_adder5(10)`

			`verify(inc(1) == 2)`
			`verify(plus10(-2) == 8)`

			`print "6. nesting plus free ref to global"`

			`def make_adder6(x):`
			`global global_nest_x`
			`def adder(y):`
			`return global_nest_x + y`
			`global_nest_x = x`
			`return adder`

			`inc = make_adder6(1)`
			`plus10 = make_adder6(10)`

Fix test for free ref to global. This test should have caught a recently fixed bug, but it checked for the wrong answer. 2001-01-29 21:26:53 -04:00			`verify(inc(1) == 11) # there's only one global`
PEP 227 implementation New tests cases for nested scopes. 2001-01-25 16:11:23 -04:00			`verify(plus10(-2) == 8)`

			`print "7. nearest enclosing scope"`

			`def f(x):`
			`def g(y):`
			`x = 42 # check that this masks binding in f()`
			`def h(z):`
			`return x + z`
			`return h`
			`return g(2)`

			`test_func = f(10)`
			`verify(test_func(5) == 47)`

			`print "8. mixed freevars and cellvars"`

			`def identity(x):`
Whitespace normalization. 2001-02-09 16:17:14 -04:00			`return x`
PEP 227 implementation New tests cases for nested scopes. 2001-01-25 16:11:23 -04:00
			`def f(x, y, z):`
			`def g(a, b, c):`
			`a = a + x # 3`
			`def h():`
Whitespace normalization. 2001-02-09 16:17:14 -04:00			`# z * (4 + 9)`
			`# 3 * 13`
PEP 227 implementation New tests cases for nested scopes. 2001-01-25 16:11:23 -04:00			`return identity(z * (b + y))`
			`y = c + z # 9`
			`return h`
			`return g`

			`g = f(1, 2, 3)`
			`h = g(2, 4, 6)`
Whitespace normalization. 2001-02-09 16:17:14 -04:00			`verify(h() == 39)`
PEP 227 implementation New tests cases for nested scopes. 2001-01-25 16:11:23 -04:00
			`print "9. free variable in method"`

			`def test():`
			`method_and_var = "var"`
			`class Test:`
			`def method_and_var(self):`
			`return "method"`
			`def test(self):`
			`return method_and_var`
			`def actual_global(self):`
			`return str("global")`
			`def str(self):`
			`return str(self)`
			`return Test()`

			`t = test()`
			`verify(t.test() == "var")`
			`verify(t.method_and_var() == "method")`
			`verify(t.actual_global() == "global")`

			`method_and_var = "var"`
			`class Test:`
			`# this class is not nested, so the rules are different`
			`def method_and_var(self):`
			`return "method"`
			`def test(self):`
			`return method_and_var`
			`def actual_global(self):`
			`return str("global")`
			`def str(self):`
			`return str(self)`

Fix test 9 (caught by ?!ng) Add tests for unbound locals (Nick Mathewson) 2001-02-05 13:35:20 -04:00			`t = Test()`
PEP 227 implementation New tests cases for nested scopes. 2001-01-25 16:11:23 -04:00			`verify(t.test() == "var")`
			`verify(t.method_and_var() == "method")`
			`verify(t.actual_global() == "global")`

			`print "10. recursion"`

			`def f(x):`
			`def fact(n):`
			`if n == 0:`
			`return 1`
			`else:`
			`return n * fact(n - 1)`
			`if x >= 0:`
			`return fact(x)`
			`else:`
			`raise ValueError, "x must be >= 0"`

			`verify(f(6) == 720)`


			`print "11. unoptimized namespaces"`

			`def check_syntax(s):`
			`try:`
			`compile(s, '?', 'exec')`
			`except SyntaxError:`
			`pass`
			`else:`
			`raise TestFailed`

			`# XXX for now, it is easiest to call this a syntax error:`
			`# explicit is better than implicit...`
			`test1 = \`
			`"""def unoptimized_clash1(strip):`
			`def f(s):`
			`from string import *`
			`return strip(s) # ambiguity: free or local`
			`return f`
			`"""`
			`check_syntax(test1)`

			`# a little harder to reject this one, but possible...`
			`test2 = \`
			`"""def unoptimized_clash2():`
			`from string import *`
			`def f(s):`
			`return strip(s) # ambiguity: global or local`
			`return f`
			`"""`
			`# check_syntax(test2)`

Whitespace normalization. 2001-02-09 16:17:14 -04:00			`# XXX could allow this for exec with const argument, but what's the point`
PEP 227 implementation New tests cases for nested scopes. 2001-01-25 16:11:23 -04:00			`test3 = \`
			`"""def error(y):`
			`exec "a = 1"`
			`def f(x):`
			`return x + y`
			`return f`
			`"""`
			`check_syntax(test3)`

			`test4 = \`
			`"""def f(x):`
			`def g():`
			`return x`
			`del x`
			`"""`
			`check_syntax(test4)`

			`print "12. lambdas"`

			`f1 = lambda x: lambda y: x + y`
			`inc = f1(1)`
			`plus10 = f1(10)`
			`verify(inc(1) == 2)`
			`verify(plus10(5) == 15)`

			`f2 = lambda x: (lambda : lambda y: x + y)()`
			`inc = f2(1)`
			`plus10 = f2(10)`
			`verify(inc(1) == 2)`
			`verify(plus10(5) == 15)`

			`f3 = lambda x: lambda y: global_x + y`
			`global_x = 1`
			`inc = f3(None)`
			`verify(inc(2) == 3)`

			`f8 = lambda x, y, z: lambda a, b, c: lambda : z * (b + y)`
			`g = f8(1, 2, 3)`
			`h = g(2, 4, 6)`
			`verify(h() == 18)`
Fix test 9 (caught by ?!ng) Add tests for unbound locals (Nick Mathewson) 2001-02-05 13:35:20 -04:00
			`print "13. UnboundLocal"`

			`def errorInOuter():`
			`print y`
			`def inner():`
			`return y`
			`y = 1`

			`def errorInInner():`
			`def inner():`
			`return y`
			`inner()`
			`y = 1`

			`try:`
			`errorInOuter()`
			`except UnboundLocalError:`
			`pass`
			`else:`
			`raise TestFailed`

			`try:`
			`errorInInner()`
			`except UnboundLocalError:`
			`pass`
			`else:`
			`raise TestFailed`