ladybird/Userland/Libraries/LibTest/JavaScriptTestRunner.h

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/*
* Copyright (c) 2020, Matthew Olsson <mattco@serenityos.org>
* Copyright (c) 2020-2021, Linus Groh <linusg@serenityos.org>
* Copyright (c) 2021, Ali Mohammad Pur <mpfard@serenityos.org>
* Copyright (c) 2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include <AK/ByteBuffer.h>
#include <AK/JsonObject.h>
#include <AK/JsonValue.h>
#include <AK/LexicalPath.h>
#include <AK/QuickSort.h>
#include <AK/Result.h>
#include <AK/Tuple.h>
#include <LibCore/DirIterator.h>
#include <LibCore/File.h>
#include <LibCore/Stream.h>
#include <LibJS/Bytecode/Interpreter.h>
#include <LibJS/Interpreter.h>
#include <LibJS/Lexer.h>
#include <LibJS/Parser.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/JSONObject.h>
#include <LibJS/Runtime/TypedArray.h>
#include <LibJS/Runtime/WeakMap.h>
#include <LibJS/Runtime/WeakSet.h>
#include <LibJS/Script.h>
#include <LibJS/SourceTextModule.h>
#include <LibTest/Results.h>
#include <LibTest/TestRunner.h>
#include <fcntl.h>
#include <sys/time.h>
#include <unistd.h>
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#ifdef __serenity__
# include <serenity.h>
#endif
#define STRCAT(x, y) __STRCAT(x, y)
#define STRSTRCAT(x, y) __STRSTRCAT(x, y)
#define __STRCAT(x, y) x #y
#define __STRSTRCAT(x, y) x y
// Note: This is a little weird, so here's an explanation:
// If the vararg isn't given, the tuple initializer will simply expand to `fn, ::Test::JS::__testjs_last<1>()`
// and if it _is_ given (say as `A`), the tuple initializer will expand to `fn, ::Test::JS::__testjs_last<1, A>()`, which will end up being evaluated as `A`
// and if multiple args are given, the static_assert will be sad.
#define __TESTJS_REGISTER_GLOBAL_FUNCTION(name, fn, ...) \
struct __TestJS_register_##fn { \
static_assert( \
::Test::JS::__testjs_count(__VA_ARGS__) <= 1, \
STRCAT(STRSTRCAT(STRCAT("Expected at most three arguments to TESTJS_GLOBAL_FUNCTION at line", __LINE__), ", in file "), __FILE__)); \
__TestJS_register_##fn() noexcept \
{ \
::Test::JS::s_exposed_global_functions.set( \
name, \
{ fn, ::Test::JS::__testjs_last<1, ##__VA_ARGS__>() }); \
} \
} __testjs_register_##fn {};
#define TESTJS_GLOBAL_FUNCTION(function, exposed_name, ...) \
JS_DECLARE_NATIVE_FUNCTION(function); \
__TESTJS_REGISTER_GLOBAL_FUNCTION(#exposed_name, function, ##__VA_ARGS__); \
JS_DEFINE_NATIVE_FUNCTION(function)
#define TESTJS_MAIN_HOOK() \
struct __TestJS_main_hook { \
__TestJS_main_hook() \
{ \
::Test::JS::g_main_hook = hook; \
} \
static void hook(); \
} __testjs_common_register_##name {}; \
void __TestJS_main_hook::hook()
#define TESTJS_PROGRAM_FLAG(flag, help_string, long_name, short_name) \
bool flag { false }; \
struct __TestJS_flag_hook_##flag { \
__TestJS_flag_hook_##flag() \
{ \
::Test::JS::g_extra_args.set(&(flag), { help_string, long_name, short_name }); \
}; \
} __testjs_flag_hook_##flag;
#define TEST_ROOT(path) \
String Test::JS::g_test_root_fragment = path
#define TESTJS_RUN_FILE_FUNCTION(...) \
struct __TestJS_run_file { \
__TestJS_run_file() \
{ \
::Test::JS::g_run_file = hook; \
} \
static ::Test::JS::IntermediateRunFileResult hook(const String&, JS::Interpreter&, JS::ExecutionContext&); \
} __testjs_common_run_file {}; \
::Test::JS::IntermediateRunFileResult __TestJS_run_file::hook(__VA_ARGS__)
#define TESTJS_CREATE_INTERPRETER_HOOK(...) \
struct __TestJS_create_interpreter_hook { \
__TestJS_create_interpreter_hook() \
{ \
::Test::JS::g_create_interpreter_hook = hook; \
} \
static NonnullOwnPtr<JS::Interpreter> hook(); \
} __testjs_create_interpreter_hook {}; \
NonnullOwnPtr<JS::Interpreter> __TestJS_create_interpreter_hook::hook(__VA_ARGS__)
namespace Test::JS {
namespace JS = ::JS;
template<typename... Args>
static consteval size_t __testjs_count(Args...) { return sizeof...(Args); }
template<auto... Values>
static consteval size_t __testjs_last()
{
Array values { Values... };
return values[values.size() - 1U];
}
static constexpr auto TOP_LEVEL_TEST_NAME = "__$$TOP_LEVEL$$__";
extern RefPtr<JS::VM> g_vm;
extern bool g_collect_on_every_allocation;
extern bool g_run_bytecode;
extern String g_currently_running_test;
struct FunctionWithLength {
JS::ThrowCompletionOr<JS::Value> (*function)(JS::VM&, JS::GlobalObject&);
size_t length { 0 };
};
extern HashMap<String, FunctionWithLength> s_exposed_global_functions;
extern String g_test_root_fragment;
extern String g_test_root;
extern int g_test_argc;
extern char** g_test_argv;
extern Function<void()> g_main_hook;
extern Function<NonnullOwnPtr<JS::Interpreter>()> g_create_interpreter_hook;
extern HashMap<bool*, Tuple<String, String, char>> g_extra_args;
struct ParserError {
JS::Parser::Error error;
String hint;
};
struct JSFileResult {
String name;
Optional<ParserError> error {};
double time_taken { 0 };
// A failed test takes precedence over a skipped test, which both have
// precedence over a passed test
Test::Result most_severe_test_result { Test::Result::Pass };
Vector<Test::Suite> suites {};
Vector<String> logged_messages {};
};
enum class RunFileHookResult {
RunAsNormal,
SkipFile,
};
using IntermediateRunFileResult = AK::Result<JSFileResult, RunFileHookResult>;
extern IntermediateRunFileResult (*g_run_file)(const String&, JS::Interpreter&, JS::ExecutionContext&);
class TestRunner : public ::Test::TestRunner {
public:
TestRunner(String test_root, String common_path, bool print_times, bool print_progress, bool print_json)
: ::Test::TestRunner(move(test_root), print_times, print_progress, print_json)
, m_common_path(move(common_path))
{
g_test_root = m_test_root;
}
virtual ~TestRunner() = default;
protected:
virtual void do_run_single_test(const String& test_path, size_t, size_t) override;
virtual Vector<String> get_test_paths() const override;
virtual JSFileResult run_file_test(const String& test_path);
void print_file_result(const JSFileResult& file_result) const;
String m_common_path;
};
class TestRunnerGlobalObject final : public JS::GlobalObject {
JS_OBJECT(TestRunnerGlobalObject, JS::GlobalObject);
public:
TestRunnerGlobalObject() = default;
virtual ~TestRunnerGlobalObject() override = default;
virtual void initialize_global_object() override;
};
inline void TestRunnerGlobalObject::initialize_global_object()
{
Base::initialize_global_object();
define_direct_property("global", this, JS::Attribute::Enumerable);
for (auto& entry : s_exposed_global_functions) {
define_native_function(
entry.key, [fn = entry.value.function](auto& vm, auto& global_object) {
return fn(vm, global_object);
},
entry.value.length, JS::default_attributes);
}
}
inline ByteBuffer load_entire_file(StringView path)
{
auto try_load_entire_file = [](StringView const& path) -> ErrorOr<ByteBuffer> {
auto file = TRY(Core::Stream::File::open(path, Core::Stream::OpenMode::Read));
auto file_size = TRY(file->size());
auto content = TRY(ByteBuffer::create_uninitialized(file_size));
TRY(file->read(content.bytes()));
return content;
};
auto buffer_or_error = try_load_entire_file(path);
if (buffer_or_error.is_error()) {
warnln("Failed to open the following file: \"{}\", error: {}", path, buffer_or_error.release_error());
cleanup_and_exit();
}
return buffer_or_error.release_value();
}
inline AK::Result<NonnullRefPtr<JS::Script>, ParserError> parse_script(StringView path, JS::Realm& realm)
{
auto contents = load_entire_file(path);
auto script_or_errors = JS::Script::parse(contents, realm, path);
if (script_or_errors.is_error()) {
auto errors = script_or_errors.release_error();
return ParserError { errors[0], errors[0].source_location_hint(contents) };
}
return script_or_errors.release_value();
}
inline AK::Result<NonnullRefPtr<JS::SourceTextModule>, ParserError> parse_module(StringView path, JS::Realm& realm)
{
auto contents = load_entire_file(path);
auto script_or_errors = JS::SourceTextModule::parse(contents, realm, path);
if (script_or_errors.is_error()) {
auto errors = script_or_errors.release_error();
return ParserError { errors[0], errors[0].source_location_hint(contents) };
}
return script_or_errors.release_value();
}
inline ErrorOr<JsonValue> get_test_results(JS::Interpreter& interpreter)
{
auto results = MUST(interpreter.global_object().get("__TestResults__"));
auto json_string = MUST(JS::JSONObject::stringify_impl(interpreter.global_object(), results, JS::js_undefined(), JS::js_undefined()));
return JsonValue::from_string(json_string);
}
inline void TestRunner::do_run_single_test(const String& test_path, size_t, size_t)
{
auto file_result = run_file_test(test_path);
if (!m_print_json)
print_file_result(file_result);
}
inline Vector<String> TestRunner::get_test_paths() const
{
Vector<String> paths;
iterate_directory_recursively(m_test_root, [&](const String& file_path) {
if (!file_path.ends_with(".js"))
return;
if (!file_path.ends_with("test-common.js"))
paths.append(file_path);
});
quick_sort(paths);
return paths;
}
inline JSFileResult TestRunner::run_file_test(const String& test_path)
{
g_currently_running_test = test_path;
#ifdef __serenity__
auto string_id = perf_register_string(test_path.characters(), test_path.length());
perf_event(PERF_EVENT_SIGNPOST, string_id, 0);
#endif
double start_time = get_time_in_ms();
auto interpreter = JS::Interpreter::create<TestRunnerGlobalObject>(*g_vm);
LibJS: Refactor interpreter to use Script and Source Text Modules This also refactors interpreter creation to follow InitializeHostDefinedRealm, but I couldn't fit it in the title :^) This allows us to follow the spec much more closely rather than being completely ad-hoc with just the parse node instead of having all the surrounding data such as the realm of the parse node. The interpreter creation refactor creates the global execution context once and doesn't take it off the stack. This allows LibWeb to take the global execution context and manually handle it, following the HTML spec. The HTML spec calls this the "realm execution context" of the environment settings object. It also allows us to specify the globalThis type, as it can be different from the global object type. For example, on the web, Window global objects use a WindowProxy global this value to enforce the same origin policy on operations like [[GetOwnProperty]]. Finally, it allows us to directly call Program::execute in perform_eval and perform_shadow_realm_eval as this moves global_declaration_instantiation into Interpreter::run (ScriptEvaluation) as per the spec. Note that this doesn't evalulate Source Text Modules yet or refactor the bytecode interpreter, that's work for future us :^) This patch was originally build by Luke for the environment settings object change but was also needed for modules. So I (davidot) have modified it with the new completion changes and setup for that. Co-authored-by: davidot <davidot@serenityos.org>
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// Since g_vm is reused for each new interpreter, Interpreter::create will end up pushing multiple
// global execution contexts onto the VM's execution context stack. To prevent this, we immediately
// pop the global execution context off the execution context stack and manually handle pushing
// and popping it. Since the global execution context should be the only thing on the stack
// at interpreter creation, let's assert there is only one.
VERIFY(g_vm->execution_context_stack().size() == 1);
auto& global_execution_context = *g_vm->execution_context_stack().take_first();
// FIXME: This is a hack while we're refactoring Interpreter/VM stuff.
JS::VM::InterpreterExecutionScope scope(*interpreter);
interpreter->heap().set_should_collect_on_every_allocation(g_collect_on_every_allocation);
if (g_run_file) {
auto result = g_run_file(test_path, *interpreter, global_execution_context);
if (result.is_error() && result.error() == RunFileHookResult::SkipFile) {
return {
test_path,
{},
0,
Test::Result::Skip,
{},
{}
};
}
if (!result.is_error()) {
auto value = result.release_value();
for (auto& suite : value.suites) {
if (suite.most_severe_test_result == Result::Pass)
m_counts.suites_passed++;
else if (suite.most_severe_test_result == Result::Fail)
m_counts.suites_failed++;
for (auto& test : suite.tests) {
if (test.result == Result::Pass)
m_counts.tests_passed++;
else if (test.result == Result::Fail)
m_counts.tests_failed++;
else if (test.result == Result::Skip)
m_counts.tests_skipped++;
}
}
++m_counts.files_total;
m_total_elapsed_time_in_ms += value.time_taken;
return value;
}
}
LibJS: Refactor interpreter to use Script and Source Text Modules This also refactors interpreter creation to follow InitializeHostDefinedRealm, but I couldn't fit it in the title :^) This allows us to follow the spec much more closely rather than being completely ad-hoc with just the parse node instead of having all the surrounding data such as the realm of the parse node. The interpreter creation refactor creates the global execution context once and doesn't take it off the stack. This allows LibWeb to take the global execution context and manually handle it, following the HTML spec. The HTML spec calls this the "realm execution context" of the environment settings object. It also allows us to specify the globalThis type, as it can be different from the global object type. For example, on the web, Window global objects use a WindowProxy global this value to enforce the same origin policy on operations like [[GetOwnProperty]]. Finally, it allows us to directly call Program::execute in perform_eval and perform_shadow_realm_eval as this moves global_declaration_instantiation into Interpreter::run (ScriptEvaluation) as per the spec. Note that this doesn't evalulate Source Text Modules yet or refactor the bytecode interpreter, that's work for future us :^) This patch was originally build by Luke for the environment settings object change but was also needed for modules. So I (davidot) have modified it with the new completion changes and setup for that. Co-authored-by: davidot <davidot@serenityos.org>
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// FIXME: Since a new interpreter is created every time with a new realm, we no longer cache the test-common.js file as scripts are parsed for the current realm only.
// Find a way to cache this.
auto result = parse_script(m_common_path, interpreter->realm());
if (result.is_error()) {
warnln("Unable to parse test-common.js");
warnln("{}", result.error().error.to_string());
warnln("{}", result.error().hint);
cleanup_and_exit();
}
LibJS: Refactor interpreter to use Script and Source Text Modules This also refactors interpreter creation to follow InitializeHostDefinedRealm, but I couldn't fit it in the title :^) This allows us to follow the spec much more closely rather than being completely ad-hoc with just the parse node instead of having all the surrounding data such as the realm of the parse node. The interpreter creation refactor creates the global execution context once and doesn't take it off the stack. This allows LibWeb to take the global execution context and manually handle it, following the HTML spec. The HTML spec calls this the "realm execution context" of the environment settings object. It also allows us to specify the globalThis type, as it can be different from the global object type. For example, on the web, Window global objects use a WindowProxy global this value to enforce the same origin policy on operations like [[GetOwnProperty]]. Finally, it allows us to directly call Program::execute in perform_eval and perform_shadow_realm_eval as this moves global_declaration_instantiation into Interpreter::run (ScriptEvaluation) as per the spec. Note that this doesn't evalulate Source Text Modules yet or refactor the bytecode interpreter, that's work for future us :^) This patch was originally build by Luke for the environment settings object change but was also needed for modules. So I (davidot) have modified it with the new completion changes and setup for that. Co-authored-by: davidot <davidot@serenityos.org>
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auto test_script = result.release_value();
if (g_run_bytecode) {
auto executable = MUST(JS::Bytecode::Generator::generate(test_script->parse_node()));
executable->name = test_path;
if (JS::Bytecode::g_dump_bytecode)
executable->dump();
JS::Bytecode::Interpreter bytecode_interpreter(interpreter->global_object(), interpreter->realm());
MUST(bytecode_interpreter.run(*executable));
} else {
LibJS: Refactor interpreter to use Script and Source Text Modules This also refactors interpreter creation to follow InitializeHostDefinedRealm, but I couldn't fit it in the title :^) This allows us to follow the spec much more closely rather than being completely ad-hoc with just the parse node instead of having all the surrounding data such as the realm of the parse node. The interpreter creation refactor creates the global execution context once and doesn't take it off the stack. This allows LibWeb to take the global execution context and manually handle it, following the HTML spec. The HTML spec calls this the "realm execution context" of the environment settings object. It also allows us to specify the globalThis type, as it can be different from the global object type. For example, on the web, Window global objects use a WindowProxy global this value to enforce the same origin policy on operations like [[GetOwnProperty]]. Finally, it allows us to directly call Program::execute in perform_eval and perform_shadow_realm_eval as this moves global_declaration_instantiation into Interpreter::run (ScriptEvaluation) as per the spec. Note that this doesn't evalulate Source Text Modules yet or refactor the bytecode interpreter, that's work for future us :^) This patch was originally build by Luke for the environment settings object change but was also needed for modules. So I (davidot) have modified it with the new completion changes and setup for that. Co-authored-by: davidot <davidot@serenityos.org>
2022-01-16 12:16:04 +00:00
g_vm->push_execution_context(global_execution_context, interpreter->global_object());
MUST(interpreter->run(*test_script));
g_vm->pop_execution_context();
}
auto file_script = parse_script(test_path, interpreter->realm());
if (file_script.is_error())
return { test_path, file_script.error() };
if (g_run_bytecode) {
auto executable_result = JS::Bytecode::Generator::generate(file_script.value()->parse_node());
if (!executable_result.is_error()) {
auto executable = executable_result.release_value();
executable->name = test_path;
if (JS::Bytecode::g_dump_bytecode)
executable->dump();
JS::Bytecode::Interpreter bytecode_interpreter(interpreter->global_object(), interpreter->realm());
(void)bytecode_interpreter.run(*executable);
}
} else {
LibJS: Refactor interpreter to use Script and Source Text Modules This also refactors interpreter creation to follow InitializeHostDefinedRealm, but I couldn't fit it in the title :^) This allows us to follow the spec much more closely rather than being completely ad-hoc with just the parse node instead of having all the surrounding data such as the realm of the parse node. The interpreter creation refactor creates the global execution context once and doesn't take it off the stack. This allows LibWeb to take the global execution context and manually handle it, following the HTML spec. The HTML spec calls this the "realm execution context" of the environment settings object. It also allows us to specify the globalThis type, as it can be different from the global object type. For example, on the web, Window global objects use a WindowProxy global this value to enforce the same origin policy on operations like [[GetOwnProperty]]. Finally, it allows us to directly call Program::execute in perform_eval and perform_shadow_realm_eval as this moves global_declaration_instantiation into Interpreter::run (ScriptEvaluation) as per the spec. Note that this doesn't evalulate Source Text Modules yet or refactor the bytecode interpreter, that's work for future us :^) This patch was originally build by Luke for the environment settings object change but was also needed for modules. So I (davidot) have modified it with the new completion changes and setup for that. Co-authored-by: davidot <davidot@serenityos.org>
2022-01-16 12:16:04 +00:00
g_vm->push_execution_context(global_execution_context, interpreter->global_object());
(void)interpreter->run(file_script.value());
g_vm->pop_execution_context();
}
auto test_json = get_test_results(*interpreter);
if (test_json.is_error()) {
warnln("Received malformed JSON from test \"{}\"", test_path);
cleanup_and_exit();
}
JSFileResult file_result { test_path.substring(m_test_root.length() + 1, test_path.length() - m_test_root.length() - 1) };
// Collect logged messages
auto user_output = MUST(interpreter->global_object().get("__UserOutput__"));
auto& arr = user_output.as_array();
for (auto& entry : arr.indexed_properties()) {
auto message = MUST(arr.get(entry.index()));
file_result.logged_messages.append(message.to_string_without_side_effects());
}
test_json.value().as_object().for_each_member([&](const String& suite_name, const JsonValue& suite_value) {
Test::Suite suite { suite_name };
VERIFY(suite_value.is_object());
suite_value.as_object().for_each_member([&](const String& test_name, const JsonValue& test_value) {
Test::Case test { test_name, Test::Result::Fail, "" };
VERIFY(test_value.is_object());
VERIFY(test_value.as_object().has("result"));
auto result = test_value.as_object().get("result");
VERIFY(result.is_string());
auto result_string = result.as_string();
if (result_string == "pass") {
test.result = Test::Result::Pass;
m_counts.tests_passed++;
} else if (result_string == "fail") {
test.result = Test::Result::Fail;
m_counts.tests_failed++;
suite.most_severe_test_result = Test::Result::Fail;
VERIFY(test_value.as_object().has("details"));
auto details = test_value.as_object().get("details");
VERIFY(result.is_string());
test.details = details.as_string();
} else {
test.result = Test::Result::Skip;
if (suite.most_severe_test_result == Test::Result::Pass)
suite.most_severe_test_result = Test::Result::Skip;
m_counts.tests_skipped++;
}
suite.tests.append(test);
});
if (suite.most_severe_test_result == Test::Result::Fail) {
m_counts.suites_failed++;
file_result.most_severe_test_result = Test::Result::Fail;
} else {
if (suite.most_severe_test_result == Test::Result::Skip && file_result.most_severe_test_result == Test::Result::Pass)
file_result.most_severe_test_result = Test::Result::Skip;
m_counts.suites_passed++;
}
file_result.suites.append(suite);
});
m_counts.files_total++;
file_result.time_taken = get_time_in_ms() - start_time;
m_total_elapsed_time_in_ms += file_result.time_taken;
return file_result;
}
inline void TestRunner::print_file_result(const JSFileResult& file_result) const
{
if (file_result.most_severe_test_result == Test::Result::Fail || file_result.error.has_value()) {
print_modifiers({ BG_RED, FG_BLACK, FG_BOLD });
out(" FAIL ");
print_modifiers({ CLEAR });
} else {
if (m_print_times || file_result.most_severe_test_result != Test::Result::Pass) {
print_modifiers({ BG_GREEN, FG_BLACK, FG_BOLD });
out(" PASS ");
print_modifiers({ CLEAR });
} else {
return;
}
}
out(" {}", file_result.name);
if (m_print_times) {
print_modifiers({ CLEAR, ITALIC, FG_GRAY });
if (file_result.time_taken < 1000) {
outln(" ({}ms)", static_cast<int>(file_result.time_taken));
} else {
outln(" ({:3}s)", file_result.time_taken / 1000.0);
}
print_modifiers({ CLEAR });
} else {
outln();
}
if (!file_result.logged_messages.is_empty()) {
print_modifiers({ FG_GRAY, FG_BOLD });
#ifdef __serenity__
outln(" Console output:");
#else
// This emoji has a second invisible byte after it. The one above does not
outln(" Console output:");
#endif
print_modifiers({ CLEAR, FG_GRAY });
for (auto& message : file_result.logged_messages)
outln(" {}", message);
}
if (file_result.error.has_value()) {
auto test_error = file_result.error.value();
print_modifiers({ FG_RED });
#ifdef __serenity__
outln(" ❌ The file failed to parse");
#else
// No invisible byte here, but the spacing still needs to be altered on the host
outln(" ❌ The file failed to parse");
#endif
outln();
print_modifiers({ FG_GRAY });
for (auto& message : test_error.hint.split('\n', true)) {
outln(" {}", message);
}
print_modifiers({ FG_RED });
outln(" {}", test_error.error.to_string());
outln();
return;
}
if (file_result.most_severe_test_result != Test::Result::Pass) {
for (auto& suite : file_result.suites) {
if (suite.most_severe_test_result == Test::Result::Pass)
continue;
bool failed = suite.most_severe_test_result == Test::Result::Fail;
print_modifiers({ FG_GRAY, FG_BOLD });
if (failed) {
#ifdef __serenity__
out(" ❌ Suite: ");
#else
// No invisible byte here, but the spacing still needs to be altered on the host
out(" ❌ Suite: ");
#endif
} else {
#ifdef __serenity__
out(" ⚠ Suite: ");
#else
// This emoji has a second invisible byte after it. The one above does not
out(" ⚠️ Suite: ");
#endif
}
print_modifiers({ CLEAR, FG_GRAY });
if (suite.name == TOP_LEVEL_TEST_NAME) {
outln("<top-level>");
} else {
outln("{}", suite.name);
}
print_modifiers({ CLEAR });
for (auto& test : suite.tests) {
if (test.result == Test::Result::Pass)
continue;
print_modifiers({ FG_GRAY, FG_BOLD });
out(" Test: ");
if (test.result == Test::Result::Fail) {
print_modifiers({ CLEAR, FG_RED });
outln("{} (failed):", test.name);
outln(" {}", test.details);
} else {
print_modifiers({ CLEAR, FG_ORANGE });
outln("{} (skipped)", test.name);
}
print_modifiers({ CLEAR });
}
}
}
}
}