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84b060ce29
rust/src/libsyntax/test.rs
Huon Wilson 84b060ce29 Add #[allow_internal_unstable] to track stability for macros better. 
Unstable items used in a macro expansion will now always trigger
stability warnings, *unless* the unstable items are directly inside a
macro marked with `#[allow_internal_unstable]`. IOW, the compiler warns
unless the span of the unstable item is a subspan of the definition of a
macro marked with that attribute.

E.g.

    #[allow_internal_unstable]
    macro_rules! foo {
        ($e: expr) => {{
            $e;
            unstable(); // no warning
            only_called_by_foo!();
        }}
    }

    macro_rules! only_called_by_foo {
        () => { unstable() } // warning
    }

    foo!(unstable()) // warning

The unstable inside `foo` is fine, due to the attribute. But the
`unstable` inside `only_called_by_foo` is not, since that macro doesn't
have the attribute, and the `unstable` passed into `foo` is also not
fine since it isn't contained in the macro itself (that is, even though
it is only used directly in the macro).

In the process this makes the stability tracking much more precise,
e.g. previously `println!("{}", unstable())` got no warning, but now it
does. As such, this is a bug fix that may cause [breaking-change]s.

The attribute is definitely feature gated, since it explicitly allows
side-stepping the feature gating system.
2015-03-06 00:18:28 +11:00

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// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
// Code that generates a test runner to run all the tests in a crate
#![allow(dead_code)]
#![allow(unused_imports)]
use self::HasTestSignature::*;
use std::slice;
use std::mem;
use std::vec;
use ast_util::*;
use attr::AttrMetaMethods;
use attr;
use codemap::{DUMMY_SP, Span, ExpnInfo, NameAndSpan, MacroAttribute};
use codemap;
use diagnostic;
use config;
use ext::base::ExtCtxt;
use ext::build::AstBuilder;
use ext::expand::ExpansionConfig;
use fold::{Folder, MoveMap};
use fold;
use owned_slice::OwnedSlice;
use parse::token::InternedString;
use parse::{token, ParseSess};
use print::pprust;
use {ast, ast_util};
use ptr::P;
use util::small_vector::SmallVector;
enum ShouldFail {
No,
Yes(Option<InternedString>),
}
struct Test {
span: Span,
path: Vec<ast::Ident> ,
bench: bool,
ignore: bool,
should_fail: ShouldFail
}
struct TestCtxt<'a> {
sess: &'a ParseSess,
span_diagnostic: &'a diagnostic::SpanHandler,
path: Vec<ast::Ident>,
ext_cx: ExtCtxt<'a>,
testfns: Vec<Test>,
reexport_test_harness_main: Option<InternedString>,
is_test_crate: bool,
config: ast::CrateConfig,
// top-level re-export submodule, filled out after folding is finished
toplevel_reexport: Option<ast::Ident>,
}
// Traverse the crate, collecting all the test functions, eliding any
// existing main functions, and synthesizing a main test harness
pub fn modify_for_testing(sess: &ParseSess,
cfg: &ast::CrateConfig,
krate: ast::Crate,
span_diagnostic: &diagnostic::SpanHandler) -> ast::Crate {
// We generate the test harness when building in the 'test'
// configuration, either with the '--test' or '--cfg test'
// command line options.
let should_test = attr::contains_name(&krate.config, "test");
// Check for #[reexport_test_harness_main = "some_name"] which
// creates a `use some_name = __test::main;`. This needs to be
// unconditional, so that the attribute is still marked as used in
// non-test builds.
let reexport_test_harness_main =
attr::first_attr_value_str_by_name(&krate.attrs,
"reexport_test_harness_main");
if should_test {
generate_test_harness(sess, reexport_test_harness_main, krate, cfg, span_diagnostic)
} else {
strip_test_functions(krate)
}
}
struct TestHarnessGenerator<'a> {
cx: TestCtxt<'a>,
tests: Vec<ast::Ident>,
// submodule name, gensym'd identifier for re-exports
tested_submods: Vec<(ast::Ident, ast::Ident)>,
}
impl<'a> fold::Folder for TestHarnessGenerator<'a> {
fn fold_crate(&mut self, c: ast::Crate) -> ast::Crate {
let mut folded = fold::noop_fold_crate(c, self);
// Add a special __test module to the crate that will contain code
// generated for the test harness
let (mod_, reexport) = mk_test_module(&mut self.cx);
match reexport {
Some(re) => folded.module.items.push(re),
None => {}
}
folded.module.items.push(mod_);
folded
}
fn fold_item(&mut self, i: P<ast::Item>) -> SmallVector<P<ast::Item>> {
let ident = i.ident;
if ident.name != token::special_idents::invalid.name {
self.cx.path.push(ident);
}
debug!("current path: {}",
ast_util::path_name_i(&self.cx.path));
if is_test_fn(&self.cx, &*i) || is_bench_fn(&self.cx, &*i) {
match i.node {
ast::ItemFn(_, ast::Unsafety::Unsafe, _, _, _) => {
let diag = self.cx.span_diagnostic;
diag.span_fatal(i.span,
"unsafe functions cannot be used for \
tests");
}
_ => {
debug!("this is a test function");
let test = Test {
span: i.span,
path: self.cx.path.clone(),
bench: is_bench_fn(&self.cx, &*i),
ignore: is_ignored(&*i),
should_fail: should_fail(&*i)
};
self.cx.testfns.push(test);
self.tests.push(i.ident);
// debug!("have {} test/bench functions",
// cx.testfns.len());
}
}
}
// We don't want to recurse into anything other than mods, since
// mods or tests inside of functions will break things
let res = match i.node {
ast::ItemMod(..) => fold::noop_fold_item(i, self),
_ => SmallVector::one(i),
};
if ident.name != token::special_idents::invalid.name {
self.cx.path.pop();
}
res
}
fn fold_mod(&mut self, m: ast::Mod) -> ast::Mod {
let tests = mem::replace(&mut self.tests, Vec::new());
let tested_submods = mem::replace(&mut self.tested_submods, Vec::new());
let mut mod_folded = fold::noop_fold_mod(m, self);
let tests = mem::replace(&mut self.tests, tests);
let tested_submods = mem::replace(&mut self.tested_submods, tested_submods);
// Remove any #[main] from the AST so it doesn't clash with
// the one we're going to add. Only if compiling an executable.
mod_folded.items = mem::replace(&mut mod_folded.items, vec![]).move_map(|item| {
item.map(|ast::Item {id, ident, attrs, node, vis, span}| {
ast::Item {
id: id,
ident: ident,
attrs: attrs.into_iter().filter_map(|attr| {
if !attr.check_name("main") {
Some(attr)
} else {
None
}
}).collect(),
node: node,
vis: vis,
span: span
}
})
});
if !tests.is_empty() || !tested_submods.is_empty() {
let (it, sym) = mk_reexport_mod(&mut self.cx, tests, tested_submods);
mod_folded.items.push(it);
if !self.cx.path.is_empty() {
self.tested_submods.push((self.cx.path[self.cx.path.len()-1], sym));
} else {
debug!("pushing nothing, sym: {:?}", sym);
self.cx.toplevel_reexport = Some(sym);
}
}
mod_folded
}
}
fn mk_reexport_mod(cx: &mut TestCtxt, tests: Vec<ast::Ident>,
tested_submods: Vec<(ast::Ident, ast::Ident)>) -> (P<ast::Item>, ast::Ident) {
let super_ = token::str_to_ident("super");
let items = tests.into_iter().map(|r| {
cx.ext_cx.item_use_simple(DUMMY_SP, ast::Public,
cx.ext_cx.path(DUMMY_SP, vec![super_, r]))
}).chain(tested_submods.into_iter().map(|(r, sym)| {
let path = cx.ext_cx.path(DUMMY_SP, vec![super_, r, sym]);
cx.ext_cx.item_use_simple_(DUMMY_SP, ast::Public, r, path)
}));
let reexport_mod = ast::Mod {
inner: DUMMY_SP,
items: items.collect(),
};
let sym = token::gensym_ident("__test_reexports");
let it = P(ast::Item {
ident: sym.clone(),
attrs: Vec::new(),
id: ast::DUMMY_NODE_ID,
node: ast::ItemMod(reexport_mod),
vis: ast::Public,
span: DUMMY_SP,
});
(it, sym)
}
fn generate_test_harness(sess: &ParseSess,
reexport_test_harness_main: Option<InternedString>,
krate: ast::Crate,
cfg: &ast::CrateConfig,
sd: &diagnostic::SpanHandler) -> ast::Crate {
let mut cx: TestCtxt = TestCtxt {
sess: sess,
span_diagnostic: sd,
ext_cx: ExtCtxt::new(sess, cfg.clone(),
ExpansionConfig::default("test".to_string())),
path: Vec::new(),
testfns: Vec::new(),
reexport_test_harness_main: reexport_test_harness_main,
is_test_crate: is_test_crate(&krate),
config: krate.config.clone(),
toplevel_reexport: None,
};
cx.ext_cx.bt_push(ExpnInfo {
call_site: DUMMY_SP,
callee: NameAndSpan {
name: "test".to_string(),
format: MacroAttribute,
span: None,
allow_internal_unstable: false,
}
});
let mut fold = TestHarnessGenerator {
cx: cx,
tests: Vec::new(),
tested_submods: Vec::new(),
};
let res = fold.fold_crate(krate);
fold.cx.ext_cx.bt_pop();
return res;
}
fn strip_test_functions(krate: ast::Crate) -> ast::Crate {
// When not compiling with --test we should not compile the
// #[test] functions
config::strip_items(krate, |attrs| {
!attr::contains_name(&attrs[..], "test") &&
!attr::contains_name(&attrs[..], "bench")
})
}
/// Craft a span that will be ignored by the stability lint's
/// call to codemap's is_internal check.
/// The expanded code calls some unstable functions in the test crate.
fn ignored_span(cx: &TestCtxt, sp: Span) -> Span {
let info = ExpnInfo {
call_site: DUMMY_SP,
callee: NameAndSpan {
name: "test".to_string(),
format: MacroAttribute,
span: None,
allow_internal_unstable: true,
}
};
let expn_id = cx.sess.span_diagnostic.cm.record_expansion(info);
let mut sp = sp;
sp.expn_id = expn_id;
return sp;
}
#[derive(PartialEq)]
enum HasTestSignature {
Yes,
No,
NotEvenAFunction,
}
fn is_test_fn(cx: &TestCtxt, i: &ast::Item) -> bool {
let has_test_attr = attr::contains_name(&i.attrs, "test");
fn has_test_signature(i: &ast::Item) -> HasTestSignature {
match &i.node {
&ast::ItemFn(ref decl, _, _, ref generics, _) => {
let no_output = match decl.output {
ast::DefaultReturn(..) => true,
ast::Return(ref t) if t.node == ast::TyTup(vec![]) => true,
_ => false
};
if decl.inputs.is_empty()
&& no_output
&& !generics.is_parameterized() {
Yes
} else {
No
}
}
_ => NotEvenAFunction,
}
}
if has_test_attr {
let diag = cx.span_diagnostic;
match has_test_signature(i) {
Yes => {},
No => diag.span_err(i.span, "functions used as tests must have signature fn() -> ()"),
NotEvenAFunction => diag.span_err(i.span,
"only functions may be used as tests"),
}
}
return has_test_attr && has_test_signature(i) == Yes;
}
fn is_bench_fn(cx: &TestCtxt, i: &ast::Item) -> bool {
let has_bench_attr = attr::contains_name(&i.attrs, "bench");
fn has_test_signature(i: &ast::Item) -> bool {
match i.node {
ast::ItemFn(ref decl, _, _, ref generics, _) => {
let input_cnt = decl.inputs.len();
let no_output = match decl.output {
ast::DefaultReturn(..) => true,
ast::Return(ref t) if t.node == ast::TyTup(vec![]) => true,
_ => false
};
let tparm_cnt = generics.ty_params.len();
// NB: inadequate check, but we're running
// well before resolve, can't get too deep.
input_cnt == 1
&& no_output && tparm_cnt == 0
}
_ => false
}
}
if has_bench_attr && !has_test_signature(i) {
let diag = cx.span_diagnostic;
diag.span_err(i.span, "functions used as benches must have signature \
`fn(&mut Bencher) -> ()`");
}
return has_bench_attr && has_test_signature(i);
}
fn is_ignored(i: &ast::Item) -> bool {
i.attrs.iter().any(|attr| attr.check_name("ignore"))
}
fn should_fail(i: &ast::Item) -> ShouldFail {
match i.attrs.iter().find(|attr| attr.check_name("should_fail")) {
Some(attr) => {
let msg = attr.meta_item_list()
.and_then(|list| list.iter().find(|mi| mi.check_name("expected")))
.and_then(|mi| mi.value_str());
ShouldFail::Yes(msg)
}
None => ShouldFail::No,
}
}
/*
We're going to be building a module that looks more or less like:
mod __test {
extern crate test (name = "test", vers = "...");
fn main() {
test::test_main_static(&::os::args()[], tests)
}
static tests : &'static [test::TestDescAndFn] = &[
... the list of tests in the crate ...
];
}
*/
fn mk_std(cx: &TestCtxt) -> P<ast::Item> {
let id_test = token::str_to_ident("test");
let (vi, vis, ident) = if cx.is_test_crate {
(ast::ItemUse(
P(nospan(ast::ViewPathSimple(id_test,
path_node(vec!(id_test)))))),
ast::Public, token::special_idents::invalid)
} else {
(ast::ItemExternCrate(None), ast::Inherited, id_test)
};
P(ast::Item {
id: ast::DUMMY_NODE_ID,
ident: ident,
node: vi,
attrs: vec![],
vis: vis,
span: DUMMY_SP
})
}
fn mk_main(cx: &mut TestCtxt) -> P<ast::Item> {
// Writing this out by hand with 'ignored_span':
// pub fn main() {
// #![main]
// use std::slice::AsSlice;
// test::test_main_static(::std::os::args().as_slice(), TESTS);
// }
let sp = ignored_span(cx, DUMMY_SP);
let ecx = &cx.ext_cx;
// test::test_main_static
let test_main_path = ecx.path(sp, vec![token::str_to_ident("test"),
token::str_to_ident("test_main_static")]);
// ::std::env::args
let os_args_path = ecx.path_global(sp, vec![token::str_to_ident("std"),
token::str_to_ident("env"),
token::str_to_ident("args")]);
// ::std::env::args()
let os_args_path_expr = ecx.expr_path(os_args_path);
let call_os_args = ecx.expr_call(sp, os_args_path_expr, vec![]);
// test::test_main_static(...)
let test_main_path_expr = ecx.expr_path(test_main_path);
let tests_ident_expr = ecx.expr_ident(sp, token::str_to_ident("TESTS"));
let call_test_main = ecx.expr_call(sp, test_main_path_expr,
vec![call_os_args, tests_ident_expr]);
let call_test_main = ecx.stmt_expr(call_test_main);
// #![main]
let main_meta = ecx.meta_word(sp, token::intern_and_get_ident("main"));
let main_attr = ecx.attribute(sp, main_meta);
// pub fn main() { ... }
let main_ret_ty = ecx.ty(sp, ast::TyTup(vec![]));
let main_body = ecx.block_all(sp, vec![call_test_main], None);
let main = ast::ItemFn(ecx.fn_decl(vec![], main_ret_ty),
ast::Unsafety::Normal, ::abi::Rust, empty_generics(), main_body);
let main = P(ast::Item {
ident: token::str_to_ident("main"),
attrs: vec![main_attr],
id: ast::DUMMY_NODE_ID,
node: main,
vis: ast::Public,
span: sp
});
return main;
}
fn mk_test_module(cx: &mut TestCtxt) -> (P<ast::Item>, Option<P<ast::Item>>) {
// Link to test crate
let import = mk_std(cx);
// A constant vector of test descriptors.
let tests = mk_tests(cx);
// The synthesized main function which will call the console test runner
// with our list of tests
let mainfn = mk_main(cx);
let testmod = ast::Mod {
inner: DUMMY_SP,
items: vec![import, mainfn, tests],
};
let item_ = ast::ItemMod(testmod);
let mod_ident = token::gensym_ident("__test");
let item = P(ast::Item {
id: ast::DUMMY_NODE_ID,
ident: mod_ident,
attrs: vec![],
node: item_,
vis: ast::Public,
span: DUMMY_SP,
});
let reexport = cx.reexport_test_harness_main.as_ref().map(|s| {
// building `use <ident> = __test::main`
let reexport_ident = token::str_to_ident(&s);
let use_path =
nospan(ast::ViewPathSimple(reexport_ident,
path_node(vec![mod_ident, token::str_to_ident("main")])));
P(ast::Item {
id: ast::DUMMY_NODE_ID,
ident: token::special_idents::invalid,
attrs: vec![],
node: ast::ItemUse(P(use_path)),
vis: ast::Inherited,
span: DUMMY_SP
})
});
debug!("Synthetic test module:\n{}\n", pprust::item_to_string(&*item));
(item, reexport)
}
fn nospan<T>(t: T) -> codemap::Spanned<T> {
codemap::Spanned { node: t, span: DUMMY_SP }
}
fn path_node(ids: Vec<ast::Ident> ) -> ast::Path {
ast::Path {
span: DUMMY_SP,
global: false,
segments: ids.into_iter().map(|identifier| ast::PathSegment {
identifier: identifier,
parameters: ast::PathParameters::none(),
}).collect()
}
}
fn mk_tests(cx: &TestCtxt) -> P<ast::Item> {
// The vector of test_descs for this crate
let test_descs = mk_test_descs(cx);
// FIXME #15962: should be using quote_item, but that stringifies
// __test_reexports, causing it to be reinterned, losing the
// gensym information.
let sp = DUMMY_SP;
let ecx = &cx.ext_cx;
let struct_type = ecx.ty_path(ecx.path(sp, vec![ecx.ident_of("self"),
ecx.ident_of("test"),
ecx.ident_of("TestDescAndFn")]));
let static_lt = ecx.lifetime(sp, token::special_idents::static_lifetime.name);
// &'static [self::test::TestDescAndFn]
let static_type = ecx.ty_rptr(sp,
ecx.ty(sp, ast::TyVec(struct_type)),
Some(static_lt),
ast::MutImmutable);
// static TESTS: $static_type = &[...];
ecx.item_const(sp,
ecx.ident_of("TESTS"),
static_type,
test_descs)
}
fn is_test_crate(krate: &ast::Crate) -> bool {
match attr::find_crate_name(&krate.attrs) {
Some(ref s) if "test" == &s[..] => true,
_ => false
}
}
fn mk_test_descs(cx: &TestCtxt) -> P<ast::Expr> {
debug!("building test vector from {} tests", cx.testfns.len());
P(ast::Expr {
id: ast::DUMMY_NODE_ID,
node: ast::ExprAddrOf(ast::MutImmutable,
P(ast::Expr {
id: ast::DUMMY_NODE_ID,
node: ast::ExprVec(cx.testfns.iter().map(|test| {
mk_test_desc_and_fn_rec(cx, test)
}).collect()),
span: DUMMY_SP,
})),
span: DUMMY_SP,
})
}
fn mk_test_desc_and_fn_rec(cx: &TestCtxt, test: &Test) -> P<ast::Expr> {
// FIXME #15962: should be using quote_expr, but that stringifies
// __test_reexports, causing it to be reinterned, losing the
// gensym information.
let span = ignored_span(cx, test.span);
let path = test.path.clone();
let ecx = &cx.ext_cx;
let self_id = ecx.ident_of("self");
let test_id = ecx.ident_of("test");
// creates self::test::$name
let test_path = |name| {
ecx.path(span, vec![self_id, test_id, ecx.ident_of(name)])
};
// creates $name: $expr
let field = |name, expr| ecx.field_imm(span, ecx.ident_of(name), expr);
debug!("encoding {}", ast_util::path_name_i(&path[..]));
// path to the #[test] function: "foo::bar::baz"
let path_string = ast_util::path_name_i(&path[..]);
let name_expr = ecx.expr_str(span, token::intern_and_get_ident(&path_string[..]));
// self::test::StaticTestName($name_expr)
let name_expr = ecx.expr_call(span,
ecx.expr_path(test_path("StaticTestName")),
vec![name_expr]);
let ignore_expr = ecx.expr_bool(span, test.ignore);
let should_fail_path = |name| {
ecx.path(span, vec![self_id, test_id, ecx.ident_of("ShouldFail"), ecx.ident_of(name)])
};
let fail_expr = match test.should_fail {
ShouldFail::No => ecx.expr_path(should_fail_path("No")),
ShouldFail::Yes(ref msg) => {
let path = should_fail_path("Yes");
let arg = match *msg {
Some(ref msg) => ecx.expr_some(span, ecx.expr_str(span, msg.clone())),
None => ecx.expr_none(span),
};
ecx.expr_call(span, ecx.expr_path(path), vec![arg])
}
};
// self::test::TestDesc { ... }
let desc_expr = ecx.expr_struct(
span,
test_path("TestDesc"),
vec![field("name", name_expr),
field("ignore", ignore_expr),
field("should_fail", fail_expr)]);
let mut visible_path = match cx.toplevel_reexport {
Some(id) => vec![id],
None => {
let diag = cx.span_diagnostic;
diag.handler.bug("expected to find top-level re-export name, but found None");
}
};
visible_path.extend(path.into_iter());
let fn_expr = ecx.expr_path(ecx.path_global(span, visible_path));
let variant_name = if test.bench { "StaticBenchFn" } else { "StaticTestFn" };
// self::test::$variant_name($fn_expr)
let testfn_expr = ecx.expr_call(span, ecx.expr_path(test_path(variant_name)), vec![fn_expr]);
// self::test::TestDescAndFn { ... }
ecx.expr_struct(span,
test_path("TestDescAndFn"),
vec![field("desc", desc_expr),
field("testfn", testfn_expr)])
}
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