def test_parsing_unclosed_strings():
"""
Strings that are not closed result in an parse error.
"""
with assert_raises_regexp(LispError, 'Unclosed string'):
parse('"hey, close me!')
def test_getting_tail_of_list():
"""`tail` returns the tail of the list.
The tail is the list retained after removing the first element."""
assert_equals([2, 3], evaluate(parse("(tail '(1 2 3))"), Environment()))
assert_equals([], evaluate(parse("(tail '(1))"), Environment()))
def test_calling_atom_raises_exception():
"""A function call to a non-function should result in an error."""
with assert_raises_regexp(LispError, "not a function"):
evaluate(parse("(#t 'foo 'bar)"), Environment())
with assert_raises_regexp(LispError, "not a function"):
evaluate(parse("(42)"), Environment())
def test_getting_tail_of_list():
"""`tail` returns the tail of the list.
The tail is the list retained after removing the first element."""
assert_equals([2, 3], evaluate(parse("(tail '(1 2 3))"), Environment()))
assert_equals([], evaluate(parse("(tail '(1))"), Environment()))
def test_parsing_unclosed_strings():
"""
Strings that are not closed result in an parse error.
"""
with assert_raises_regexp(LispError, 'Unclosed string'):
parse('"hey, close me!')
def test_parse_boolean():
"""Parsing single booleans.
Booleans are the special symbols #t and #f. In the ASTs they are represented
by Pythons True and False, respectively. """
assert_equals(True, parse('#t'))
assert_equals(False, parse('#f'))
def test_lambda_arguments_are_lists():
"""The parameters of a `lambda` should be a list."""
closure = evaluate(parse("(lambda (x y) (+ x y))"), Environment())
assert_true(is_list(closure.params))
with assert_raises(LispError):
evaluate(parse("(lambda not-a-list (body of fn))"), Environment())
def test_define_with_wrong_number_of_arguments():
"""Defines should have exactly two arguments, or raise an error"""
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x)"), Environment())
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x 1 2)"), Environment())
def test_checking_whether_list_is_empty():
"""The `empty` form checks whether or not a list is empty."""
assert_equals(False, evaluate(parse("(empty '(1 2 3))"), Environment()))
assert_equals(False, evaluate(parse("(empty '(1))"), Environment()))
assert_equals(True, evaluate(parse("(empty '())"), Environment()))
assert_equals(True, evaluate(parse("(empty (tail '(1)))"), Environment()))
def test_calling_with_wrong_number_of_arguments():
"""Functions should raise exceptions when called with wrong number of arguments."""
env = Environment()
evaluate(parse("(define fn (lambda (p1 p2) 'whatever))"), env)
error_msg = "wrong number of arguments, expected 2 got 3"
with assert_raises_regexp(LispError, error_msg):
evaluate(parse("(fn 1 2 3)"), env)
def test_checking_whether_list_is_empty():
"""The `empty` form checks whether or not a list is empty."""
assert_equals(False, evaluate(parse("(empty '(1 2 3))"), Environment()))
assert_equals(False, evaluate(parse("(empty '(1))"), Environment()))
assert_equals(True, evaluate(parse("(empty '())"), Environment()))
assert_equals(True, evaluate(parse("(empty (tail '(1)))"), Environment()))
def test_parse_exception_extra_paren():
"""Another exception is raised if the expression is too large.
The parse function expects to receive only one single expression. Anything
more than this, should result in the proper exception."""
with assert_raises_regexp(LispError, 'Expected EOF'):
parse('(foo (bar x y)))')
def test_parse_boolean():
"""Parsing single booleans.
Booleans are the special symbols #t and #f. In the ASTs they are represented
by Pythons True and False, respectively. """
assert_equals(True, parse('#t'))
assert_equals(False, parse('#f'))
def test_type_checking_in_cons():
"""The `cons` functions adds an atom to a list."""
with assert_raises_regexp(LispError, "First parameter to cons must be atom"):
evaluate(parse("(cons '() '(1 2 3))"), Environment())
with assert_raises_regexp(LispError, "Second parameter to cons must be list"):
evaluate(parse("(cons 1 2)"), Environment())
def test_parse_exception_extra_paren():
"""Another exception is raised if the expression is too large.
The parse function expects to receive only one single expression. Anything
more than this, should result in the proper exception."""
with assert_raises_regexp(LispError, 'Expected EOF'):
parse('(foo (bar x y)))')
def test_define_with_wrong_number_of_arguments():
"""Defines should have exactly two arguments, or raise an error"""
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x)"), Environment())
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x 1 2)"), Environment())
def test_creating_longer_lists_with_only_cons():
"""`cons` needs to evaluate it's arguments.
Like all the other special forms and functions in our language, `cons` is
call-by-value. This means that the arguments must be evaluated before we
create the list with their values."""
result = evaluate(parse("(cons 3 (cons (- 4 2) (cons 1 '())))"), Environment())
assert_equals(parse("(3 2 1)"), result)
def test_parse_integer():
"""Parsing single integer.
Integers are represented in the ASTs as Python ints.
Tip: String objects have a handy .isdigit() method.
"""
assert_equals(42, parse('42'))
assert_equals(1337, parse('1337'))
def test_parsing_strings_are_closed_by_first_closing_quotes():
"""
Strings are delimited by the first and last (unescaped) double quotes.
Thus, unescaped quotes followed by anything at all should be considered
invalid and throw an exception.
"""
with assert_raises_regexp(LispError, 'Expected EOF'):
parse('"foo" bar"')
def test_parsing_strings_are_closed_by_first_closing_quotes():
"""
Strings are delimited by the first and last (unescaped) double quotes.
Thus, unescaped quotes followed by anything at all should be considered
invalid and throw an exception.
"""
with assert_raises_regexp(LispError, 'Expected EOF'):
parse('"foo" bar"')
def test_creating_longer_lists_with_only_cons():
"""`cons` needs to evaluate it's arguments.
Like all the other special forms and functions in our language, `cons` is
call-by-value. This means that the arguments must be evaluated before we
create the list with their values."""
result = evaluate(parse("(cons 3 (cons (- 4 2) (cons 1 '())))"),
Environment())
assert_equals(parse("(3 2 1)"), result)
def test_basic_if_statement():
"""If statements are the basic control structures.
The `if` should first evaluate its first argument. If this evaluates to true, then
the second argument is evaluated and returned. Otherwise the third and last argument
is evaluated and returned instead."""
assert_equals(42, evaluate(parse("(if #t 42 1000)"), Environment()))
assert_equals(1000, evaluate(parse("(if #f 42 1000)"), Environment()))
assert_equals(True, evaluate(parse("(if #t #t #f)"), Environment()))
def test_parse_integer():
"""Parsing single integer.
Integers are represented in the ASTs as Python ints.
Tip: String objects have a handy .isdigit() method.
"""
assert_equals(42, parse('42'))
assert_equals(1337, parse('1337'))
def test_basic_if_statement():
"""If statements are the basic control structures.
The `if` should first evaluate its first argument. If this evaluates to true, then
the second argument is evaluated and returned. Otherwise the third and last argument
is evaluated and returned instead."""
assert_equals(42, evaluate(parse("(if #t 42 1000)"), Environment()))
assert_equals(1000, evaluate(parse("(if #f 42 1000)"), Environment()))
assert_equals(True, evaluate(parse("(if #t #t #f)"), Environment()))
def test_math_operators_only_work_on_numbers():
"""The math functions should only allow numbers as arguments."""
with assert_raises(LispError):
evaluate(parse("(+ 1 'foo)"), Environment())
with assert_raises(LispError):
evaluate(parse("(- 1 'foo)"), Environment())
with assert_raises(LispError):
evaluate(parse("(/ 1 'foo)"), Environment())
with assert_raises(LispError):
evaluate(parse("(mod 1 'foo)"), Environment())
def test_call_to_function_should_evaluate_arguments():
"""Call to function should evaluate all arguments.
When a function is applied, the arguments should be evaluated before being bound
to the parameter names."""
env = Environment()
closure = evaluate(parse("(lambda (a) (+ a 5))"), env)
ast = [closure, parse("(if #f 0 (+ 10 10))")]
assert_equals(25, evaluate(ast, env))
def test_math_operators_only_work_on_numbers():
"""The math functions should only allow numbers as arguments."""
with assert_raises(LispError):
evaluate(parse("(+ 1 'foo)"), Environment())
with assert_raises(LispError):
evaluate(parse("(- 1 'foo)"), Environment())
with assert_raises(LispError):
evaluate(parse("(/ 1 'foo)"), Environment())
with assert_raises(LispError):
evaluate(parse("(mod 1 'foo)"), Environment())
def test_define_with_wrong_number_of_arguments():
"""Defines should have exactly two arguments, or raise an error.
This type of check could benefit the other forms we implement as well,
and you might want to add them elsewhere. It quickly get tiresome to
test for this however, so the tests won't require you to."""
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x)"), Environment())
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x 1 2)"), Environment())
def test_parse_list_of_symbols():
"""Parsing list of only symbols.
A list is represented by a number of elements surrounded by parens. Python lists
are used to represent lists as ASTs.
Tip: The useful helper function `find_matching_paren` is already provided in
`parse.py`.
"""
assert_equals(['foo', 'bar', 'baz'], parse('(foo bar baz)'))
assert_equals([], parse('()'))
def test_define_with_wrong_number_of_arguments():
"""Defines should have exactly two arguments, or raise an error.
This type of check could benefit the other forms we implement as well,
and you might want to add them elsewhere. It quickly get tiresome to
test for this however, so the tests won't require you to."""
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x)"), Environment())
with assert_raises_regexp(LispError, "Wrong number of arguments"):
evaluate(parse("(define x 1 2)"), Environment())
def test_creating_lists_by_quoting():
"""One way to create lists is by quoting.
We have already implemented `quote` so this test should already be
passing.
The reason we need to use `quote` here is that otherwise the expression would
be seen as a call to the first element -- `1` in this case, which obviously isn't
even a function."""
assert_equals(parse("(1 2 3 #t)"),
evaluate(parse("'(1 2 3 #t)"), Environment()))
def test_parse_list_of_symbols():
"""Parsing list of only symbols.
A list is represented by a number of elements surrounded by parens. Python lists
are used to represent lists as ASTs.
Tip: The useful helper function `find_matching_paren` is already provided in
`parse.py`.
"""
assert_equals(['foo', 'bar', 'baz'], parse('(foo bar baz)'))
assert_equals([], parse('()'))
def test_creating_lists_by_quoting():
"""One way to create lists is by quoting.
We have already implemented `quote` so this test should already be
passing.
The reason we need to use `quote` here is that otherwise the expression would
be seen as a call to the first element -- `1` in this case, which obviously isn't
even a function."""
assert_equals(parse("(1 2 3 #t)"),
evaluate(parse("'(1 2 3 #t)"), Environment()))
def test_calling_very_simple_function_in_environment():
"""A call to a symbol corresponds to a call to its value in the environment.
When a symbol is the first element of the AST list, it is resolved to its value in
the environment (which should be a function closure). An AST with the variables
replaced with its value should then be evaluated instead."""
env = Environment()
evaluate(parse("(define add (lambda (x y) (+ x y)))"), env)
assert_is_instance(env.lookup("add"), Closure)
result = evaluate(parse("(add 1 2)"), env)
assert_equals(3, result)
def test_evaluating_eq_function():
""""""
assert_equals(True, evaluate(["eq", 1, 1], Environment()))
assert_equals(False, evaluate(["eq", 1, 2], Environment()))
# From this point, the ASTs might sometimes be too long or cummbersome to
# write down explicitly, and we'll use `parse` to make them for us.
# Remember, if you need to have a look at exactly what is passed to `evaluate`,
# just add a print statement.
assert_equals(True, evaluate(parse("(eq 'foo 'foo)"), Environment()))
assert_equals(False, evaluate(parse("(eq 'foo 'bar)"), Environment()))
def test_parse_list_of_mixed_types():
"""Parsing a list containing different types.
When parsing lists, make sure each of the sub-expressions are also parsed
properly."""
assert_equals(['foo', True, 123], parse('(foo #t 123)'))
def test_evaluating_eq_function():
"""The `eq` form is used to check whether two expressions are the same atom."""
assert_equals(True, evaluate(["eq", 1, 1], Environment()))
assert_equals(False, evaluate(["eq", 1, 2], Environment()))
# From this point, the ASTs might sometimes be too long or cummbersome to
# write down explicitly, and we'll use `parse` to make them for us.
# Remember, if you need to have a look at exactly what is passed to `evaluate`,
# just add a print statement in the test (or in `evaluate`).
assert_equals(True, evaluate(parse("(eq 'foo 'foo)"), Environment()))
assert_equals(False, evaluate(parse("(eq 'foo 'bar)"), Environment()))
# Lists are never equal, because lists are not atoms
assert_equals(False, evaluate(parse("(eq '(1 2 3) '(1 2 3))"), Environment()))
def test_parse_list_of_mixed_types():
"""Parsing a list containing different types.
When parsing lists, make sure each of the sub-expressions are also parsed
properly."""
assert_equals(['foo', True, 123], parse('(foo #t 123)'))
def test_parse_single_symbol():
"""Parsing a single symbol.
Symbols are represented by text strings. Parsing a single atom should result
in an AST consisting of only that symbol."""
assert_equals('foo', parse('foo'))
def test_nested_expression():
"""All functions (except `quote` wich isn't really a function) should evaluate the
arguments. Thus, nested expressions should work just fine without any further work
at this point."""
nested_expression = parse("(> (- (+ 1 3) (* 2 (mod 7 4))) 4)")
assert_equals(False, evaluate(nested_expression, Environment()))
def test_parse_single_symbol():
"""Parsing a single symbol.
Symbols are represented by text strings. Parsing a single atom should result
in an AST consisting of only that symbol."""
assert_equals('foo', parse('foo'))
def test_lambda_closure_holds_function():
"""The closure contains the parameter list and function body too."""
closure = evaluate(parse("(lambda (x y) (+ x y))"), Environment())
assert_equals(["x", "y"], closure.params)
assert_equals(["+", "x", "y"], closure.body)
def test_calling_function_recursively():
"""Tests that a named function is included in the environment
where it is evaluated."""
env = Environment()
evaluate(parse("""
(define my-fn
;; A meaningless, but recursive, function
(lambda (x)
(if (eq x 0)
42
(my-fn (- x 1)))))
"""), env)
assert_equals(42, evaluate(parse("(my-fn 0)"), env))
assert_equals(42, evaluate(parse("(my-fn 10)"), env))
def test_variable_lookup_after_define():
"""Test define and lookup variable in same environment.
This test should already be working when the above ones are passing."""
env = Environment()
evaluate(parse("(define foo (+ 2 2))"), env)
assert_equals(4, evaluate("foo", env))
def test_define():
"""Test of simple define statement.
The `define` form is used to define new bindings in the environment."""
env = Environment()
evaluate(parse("(define x 1000)"), env)
assert_equals(1000, env.lookup("x"))
def test_evaluating_eq_function():
"""The `eq` form is used to check whether two expressions are the same atom."""
assert_equals(True, evaluate(["eq", 1, 1], Environment()))
assert_equals(False, evaluate(["eq", 1, 2], Environment()))
# From this point, the ASTs might sometimes be too long or cummbersome to
# write down explicitly, and we'll use `parse` to make them for us.
# Remember, if you need to have a look at exactly what is passed to `evaluate`,
# just add a print statement in the test (or in `evaluate`).
assert_equals(True, evaluate(parse("(eq 'foo 'foo)"), Environment()))
assert_equals(False, evaluate(parse("(eq 'foo 'bar)"), Environment()))
# Lists are never equal, because lists are not atoms
assert_equals(False,
evaluate(parse("(eq '(1 2 3) '(1 2 3))"), Environment()))
def test_parse_on_nested_list():
"""Parsing should also handle nested lists properly."""
program = '(foo (bar ((#t)) x) (baz y))'
ast = ['foo',
['bar', [[True]], 'x'],
['baz', 'y']]
assert_equals(ast, parse(program))
def test_parse_on_nested_list():
"""Parsing should also handle nested lists properly."""
program = '(foo (bar ((#t)) x) (baz y))'
ast = ['foo',
['bar', [[True]], 'x'],
['baz', 'y']]
assert_equals(ast, parse(program))
def test_variable_lookup_after_define():
"""Test define and lookup variable in same environment.
This test should already be working when the above ones are passing."""
env = Environment()
evaluate(parse("(define foo (+ 2 2))"), env)
assert_equals(4, evaluate("foo", env))
def test_parsing_strings_with_escaped_double_quotes():
"""
We should be able to create strings with "-characters by escaping them.
"""
ast = parse('"Say \\"what\\" one more time!"')
assert_is_instance(ast, String)
assert_equals('Say \\"what\\" one more time!', ast.val)
def test_parse_with_extra_whitespace():
"""Excess whitespace should be removed."""
program = """
(program with much whitespace)
"""
expected_ast = ['program', 'with', 'much', 'whitespace']
assert_equals(expected_ast, parse(program))
def test_calling_lambda_directly():
"""It should be possible to define and call functions directly.
A lambda definition in the call position of an AST should be evaluated, and then
evaluated as before."""
ast = parse("((lambda (x) x) 42)")
result = evaluate(ast, Environment())
assert_equals(42, result)
def test_if_with_sub_expressions():
"""A final test with a more complex if expression.
This test should already be passing if the above ones are."""
ast = parse("""
(if (> 1 2)
(- 1000 1)
(+ 40 (- 3 1)))
""")
assert_equals(42, evaluate(ast, Environment()))
