hy/tests/compilers/test_ast.py
Gergely Nagy 439fa6eb17 core.macros: Fix a for corner case
In case for doesn't get a body, raise the appropriate, descriptive error
instead of an IndexOutOfBounds one. Also updated the failing test case.

Signed-off-by: Gergely Nagy <algernon@madhouse-project.org>
2015-08-10 10:16:25 +02:00

522 lines
15 KiB
Python

# Copyright (c) 2013 Paul Tagliamonte <paultag@debian.org>
# Copyright (c) 2013 Julien Danjou <julien@danjou.info>
#
# Permission is hereby granted, free of charge, to any person obtaining a
# copy of this software and associated documentation files (the "Software"),
# to deal in the Software without restriction, including without limitation
# the rights to use, copy, modify, merge, publish, distribute, sublicense,
# and/or sell copies of the Software, and to permit persons to whom the
# Software is furnished to do so, subject to the following conditions:
#
# The above copyright notice and this permission notice shall be included in
# all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
# THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
# FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
# DEALINGS IN THE SOFTWARE.
from __future__ import unicode_literals
from hy import HyString
from hy.models import HyObject
from hy.compiler import hy_compile
from hy.errors import HyCompileError, HyTypeError
from hy.lex.exceptions import LexException
from hy.lex import tokenize
from hy._compat import PY3
import ast
def _ast_spotcheck(arg, root, secondary):
if "." in arg:
local, full = arg.split(".", 1)
return _ast_spotcheck(full,
getattr(root, local),
getattr(secondary, local))
assert getattr(root, arg) == getattr(secondary, arg)
def can_compile(expr):
return hy_compile(tokenize(expr), "__main__")
def cant_compile(expr):
try:
hy_compile(tokenize(expr), "__main__")
assert False
except HyTypeError as e:
# Anything that can't be compiled should raise a user friendly
# error, otherwise it's a compiler bug.
assert isinstance(e.expression, HyObject)
assert e.message
return e
except HyCompileError as e:
# Anything that can't be compiled should raise a user friendly
# error, otherwise it's a compiler bug.
assert isinstance(e.exception, HyTypeError)
assert e.traceback
return e
def test_ast_bad_type():
"Make sure AST breakage can happen"
try:
hy_compile("foo", "__main__")
assert True is False
except HyCompileError:
pass
def test_ast_bad_if():
"Make sure AST can't compile invalid if"
cant_compile("(if)")
cant_compile("(if foobar)")
cant_compile("(if 1 2 3 4 5)")
def test_ast_valid_if():
"Make sure AST can't compile invalid if"
can_compile("(if foo bar)")
def test_ast_valid_unary_op():
"Make sure AST can compile valid unary operator"
can_compile("(not 2)")
can_compile("(~ 1)")
def test_ast_invalid_unary_op():
"Make sure AST can't compile invalid unary operator"
cant_compile("(not 2 3 4)")
cant_compile("(not)")
cant_compile("(not 2 3 4)")
cant_compile("(~ 2 2 3 4)")
cant_compile("(~)")
def test_ast_bad_while():
"Make sure AST can't compile invalid while"
cant_compile("(while)")
cant_compile("(while (true))")
def test_ast_good_do():
"Make sure AST can compile valid do"
can_compile("(do)")
can_compile("(do 1)")
def test_ast_good_raise():
"Make sure AST can compile valid raise"
can_compile("(raise)")
can_compile("(raise Exception)")
can_compile("(raise e)")
if PY3:
def test_ast_raise_from():
can_compile("(raise Exception :from NameError)")
def test_ast_bad_raise():
"Make sure AST can't compile invalid raise"
cant_compile("(raise Exception Exception)")
def test_ast_good_try():
"Make sure AST can compile valid try"
can_compile("(try)")
can_compile("(try 1)")
can_compile("(try 1 (except) (else 1))")
can_compile("(try 1 (else 1) (except))")
can_compile("(try 1 (finally 1) (except))")
can_compile("(try 1 (finally 1))")
can_compile("(try 1 (except) (finally 1))")
can_compile("(try 1 (except) (finally 1) (else 1))")
can_compile("(try 1 (except) (else 1) (finally 1))")
def test_ast_bad_try():
"Make sure AST can't compile invalid try"
cant_compile("(try 1 bla)")
cant_compile("(try 1 bla bla)")
cant_compile("(try (do) (else 1) (else 2))")
cant_compile("(try 1 (else 1))")
def test_ast_good_except():
"Make sure AST can compile valid except"
can_compile("(try 1 (except))")
can_compile("(try 1 (except []))")
can_compile("(try 1 (except [Foobar]))")
can_compile("(try 1 (except [[]]))")
can_compile("(try 1 (except [x FooBar]))")
can_compile("(try 1 (except [x [FooBar BarFoo]]))")
can_compile("(try 1 (except [x [FooBar BarFoo]]))")
def test_ast_bad_except():
"Make sure AST can't compile invalid except"
cant_compile("(except 1)")
cant_compile("(try 1 (except 1))")
cant_compile("(try 1 (except [1 3]))")
cant_compile("(try 1 (except [x [FooBar] BarBar]))")
def test_ast_good_assert():
"""Make sure AST can compile valid asserts. Asserts may or may not
include a label."""
can_compile("(assert 1)")
can_compile("(assert 1 \"Assert label\")")
can_compile("(assert 1 (+ \"spam \" \"eggs\"))")
can_compile("(assert 1 12345)")
can_compile("(assert 1 nil)")
can_compile("(assert 1 (+ 2 \"incoming eggsception\"))")
def test_ast_bad_assert():
"Make sure AST can't compile invalid assert"
cant_compile("(assert)")
cant_compile("(assert 1 2 3)")
cant_compile("(assert 1 [1 2] 3)")
def test_ast_good_global():
"Make sure AST can compile valid global"
can_compile("(global a)")
can_compile("(global foo bar)")
def test_ast_bad_global():
"Make sure AST can't compile invalid global"
cant_compile("(global)")
cant_compile("(global (foo))")
if PY3:
def test_ast_good_nonlocal():
"Make sure AST can compile valid nonlocal"
can_compile("(nonlocal a)")
can_compile("(nonlocal foo bar)")
def test_ast_bad_nonlocal():
"Make sure AST can't compile invalid nonlocal"
cant_compile("(nonlocal)")
cant_compile("(nonlocal (foo))")
def test_ast_good_defclass():
"Make sure AST can compile valid defclass"
can_compile("(defclass a)")
can_compile("(defclass a [])")
def test_ast_bad_defclass():
"Make sure AST can't compile invalid defclass"
cant_compile("(defclass)")
cant_compile("(defclass a null)")
cant_compile("(defclass a null null)")
def test_ast_good_lambda():
"Make sure AST can compile valid lambda"
can_compile("(lambda [])")
can_compile("(lambda [] 1)")
def test_ast_bad_lambda():
"Make sure AST can't compile invalid lambda"
cant_compile("(lambda)")
def test_ast_good_yield():
"Make sure AST can compile valid yield"
can_compile("(yield 1)")
def test_ast_bad_yield():
"Make sure AST can't compile invalid yield"
cant_compile("(yield 1 2)")
def test_ast_good_import_from():
"Make sure AST can compile valid selective import"
can_compile("(import [x [y]])")
def test_ast_good_get():
"Make sure AST can compile valid get"
can_compile("(get x y)")
def test_ast_bad_get():
"Make sure AST can't compile invalid get"
cant_compile("(get)")
cant_compile("(get 1)")
def test_ast_good_cut():
"Make sure AST can compile valid cut"
can_compile("(cut x)")
can_compile("(cut x y)")
can_compile("(cut x y z)")
can_compile("(cut x y z t)")
def test_ast_bad_cut():
"Make sure AST can't compile invalid cut"
cant_compile("(cut)")
cant_compile("(cut 1 2 3 4 5)")
def test_ast_good_take():
"Make sure AST can compile valid 'take'"
can_compile("(take 1 [2 3])")
def test_ast_good_drop():
"Make sure AST can compile valid 'drop'"
can_compile("(drop 1 [2 3])")
def test_ast_good_assoc():
"Make sure AST can compile valid assoc"
can_compile("(assoc x y z)")
def test_ast_bad_assoc():
"Make sure AST can't compile invalid assoc"
cant_compile("(assoc)")
cant_compile("(assoc 1)")
cant_compile("(assoc 1 2)")
cant_compile("(assoc 1 2 3 4)")
def test_ast_bad_with():
"Make sure AST can't compile invalid with"
cant_compile("(with*)")
cant_compile("(with* [])")
cant_compile("(with* [] (pass))")
def test_ast_valid_while():
"Make sure AST can't compile invalid while"
can_compile("(while foo bar)")
def test_ast_valid_for():
"Make sure AST can compile valid for"
can_compile("(for [a 2] (print a))")
def test_ast_invalid_for():
"Make sure AST can't compile invalid for"
cant_compile("(for* [a 1] (else 1 2))")
def test_ast_valid_let():
"Make sure AST can compile valid let"
can_compile("(let [])")
can_compile("(let [a b])")
can_compile("(let [[a 1]])")
can_compile("(let [[a 1] b])")
def test_ast_invalid_let():
"Make sure AST can't compile invalid let"
cant_compile("(let 1)")
cant_compile("(let [1])")
cant_compile("(let [[a 1 2]])")
cant_compile("(let [[]])")
cant_compile("(let [[a]])")
cant_compile("(let [[1]])")
def test_ast_expression_basics():
""" Ensure basic AST expression conversion works. """
code = can_compile("(foo bar)").body[0]
tree = ast.Expr(value=ast.Call(
func=ast.Name(
id="foo",
ctx=ast.Load(),
),
args=[
ast.Name(id="bar", ctx=ast.Load())
],
keywords=[],
starargs=None,
kwargs=None,
))
_ast_spotcheck("value.func.id", code, tree)
def test_ast_anon_fns_basics():
""" Ensure anon fns work. """
code = can_compile("(fn (x) (* x x))").body[0]
assert type(code) == ast.FunctionDef
code = can_compile("(fn (x))").body[0]
cant_compile("(fn)")
def test_ast_non_decoratable():
""" Ensure decorating garbage breaks """
cant_compile("(with-decorator (foo) (* x x))")
def test_ast_lambda_lists():
"""Ensure the compiler chokes on invalid lambda-lists"""
cant_compile('(fn [&key {"a" b} &key {"foo" bar}] [a foo])')
cant_compile('(fn [&optional a &key {"foo" bar}] [a foo])')
cant_compile('(fn [&optional [a b c]] a)')
def test_ast_print():
code = can_compile("(print \"foo\")").body[0]
assert type(code.value) == ast.Call
def test_ast_tuple():
""" Ensure tuples work. """
code = can_compile("(, 1 2 3)").body[0].value
assert type(code) == ast.Tuple
def test_argument_destructuring():
""" Ensure argument destructuring compilers. """
can_compile("(fn [[a b]] (print a b))")
cant_compile("(fn [[]] 0)")
def test_lambda_list_keywords_rest():
""" Ensure we can compile functions with lambda list keywords."""
can_compile("(fn (x &rest xs) (print xs))")
cant_compile("(fn (x &rest xs &rest ys) (print xs))")
def test_lambda_list_keywords_key():
""" Ensure we can compile functions with &key."""
can_compile("(fn (x &key {foo True}) (list x foo))")
cant_compile("(fn (x &key {bar \"baz\"} &key {foo 42}) (list x bar foo))")
def test_lambda_list_keywords_kwargs():
""" Ensure we can compile functions with &kwargs."""
can_compile("(fn (x &kwargs kw) (list x kw))")
cant_compile("(fn (x &kwargs xs &kwargs ys) (list x xs ys))")
def test_lambda_list_keywords_kwonly():
"""Ensure we can compile functions with &kwonly if we're on Python
3, or fail with an informative message on Python 2."""
kwonly_demo = "(fn [&kwonly a [b 2]] (print a b))"
if PY3:
code = can_compile(kwonly_demo)
for i, kwonlyarg_name in enumerate(('a', 'b')):
assert kwonlyarg_name == code.body[0].args.kwonlyargs[i].arg
assert code.body[0].args.kw_defaults[0] is None
assert code.body[0].args.kw_defaults[1].n == 2
else:
exception = cant_compile(kwonly_demo)
assert isinstance(exception, HyTypeError)
message, = exception.args
assert message == ("keyword-only arguments are only "
"available under Python 3")
def test_lambda_list_keywords_mixed():
""" Ensure we can mix them up."""
can_compile("(fn (x &rest xs &kwargs kw) (list x xs kw))")
cant_compile("(fn (x &rest xs &fasfkey {bar \"baz\"}))")
if PY3:
can_compile("(fn [x &rest xs &kwargs kwxs &kwonly kwoxs]"
" (list x xs kwxs kwoxs))")
def test_ast_unicode_strings():
"""Ensure we handle unicode strings correctly"""
def _compile_string(s):
hy_s = HyString(s)
hy_s.start_line = hy_s.end_line = 0
hy_s.start_column = hy_s.end_column = 0
code = hy_compile([hy_s], "__main__")
# code == ast.Module(body=[ast.Expr(value=ast.Str(s=xxx))])
return code.body[0].value.s
assert _compile_string("test") == "test"
assert _compile_string("\u03b1\u03b2") == "\u03b1\u03b2"
assert _compile_string("\xc3\xa9") == "\xc3\xa9"
def test_compile_error():
"""Ensure we get compile error in tricky cases"""
try:
can_compile("(fn [] (= 1))")
except HyTypeError as e:
assert(e.message == "`=' needs at least 2 arguments, got 1.")
else:
assert(False)
def test_for_compile_error():
"""Ensure we get compile error in tricky 'for' cases"""
try:
can_compile("(fn [] (for)")
except LexException as e:
assert(e.message == "Premature end of input")
else:
assert(False)
try:
can_compile("(fn [] (for)))")
except LexException as e:
assert(e.message == "Ran into a RPAREN where it wasn't expected.")
else:
assert(False)
try:
can_compile("(fn [] (for [x] x))")
except HyTypeError as e:
assert(e.message == "`for' requires an even number of args.")
else:
assert(False)
try:
can_compile("(fn [] (for [x xx]))")
except HyTypeError as e:
assert(e.message == "`for' requires a body to evaluate")
else:
assert(False)
try:
can_compile("(fn [] (for [x xx] (else 1)))")
except HyTypeError as e:
assert(e.message == "`for' requires a body to evaluate")
else:
assert(False)
def test_attribute_access():
"""Ensure attribute access compiles correctly"""
can_compile("(. foo bar baz)")
can_compile("(. foo [bar] baz)")
can_compile("(. foo bar [baz] [0] quux [frob])")
can_compile("(. foo bar [(+ 1 2 3 4)] quux [frob])")
cant_compile("(. foo bar :baz [0] quux [frob])")
cant_compile("(. foo bar baz (0) quux [frob])")
cant_compile("(. foo bar baz [0] quux {frob})")
def test_cons_correct():
"""Ensure cons gets compiled correctly"""
can_compile("(cons a b)")