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#include <kernel/filesystem/vfs.hpp>
#include <kernel/filesystem/open_file_descriptor.hpp>
#include <kernel/test_support/filesystem/storage_boot_module_vfs_fixture.hpp>
#include <kstd/memory>
#include <kstd/vector>
#include <catch2/catch_test_macros.hpp>
#include <cstddef>
#include <filesystem>
#include <string_view>
SCENARIO_METHOD(kernel::tests::filesystem::storage_boot_module_vfs_fixture, "VFS with dummy modules",
"[filesystem][vfs]")
{
GIVEN("an initialized boot module registry with multiple modules")
{
REQUIRE_NOTHROW(setup_modules_and_init_vfs(5));
THEN("vfs initializes and provides /dev mount")
{
auto & vfs = kernel::filesystem::vfs::get();
auto dev = vfs.open("/dev");
REQUIRE(dev != nullptr);
}
THEN("vfs initializes root filesystem with boot device if boot module is present")
{
auto & vfs = kernel::filesystem::vfs::get();
auto root_file = vfs.open("/");
REQUIRE(root_file != nullptr);
}
}
}
SCENARIO_METHOD(kernel::tests::filesystem::storage_boot_module_vfs_fixture, "VFS with file backed image",
"[filesystem][vfs][img]")
{
auto const image_path_1 = std::filesystem::path{KERNEL_TEST_ASSETS_DIR} / "ext2_1KB_fs.img";
auto const image_path_2 = std::filesystem::path{KERNEL_TEST_ASSETS_DIR} / "ext2_2KB_fs.img";
auto const image_path_3 = std::filesystem::path{KERNEL_TEST_ASSETS_DIR} / "ext2_4KB_fs.img";
GIVEN("a real image file")
{
REQUIRE(std::filesystem::exists(image_path_1));
REQUIRE_NOTHROW(setup_modules_from_img_and_init_vfs({"test_img_module"}, {image_path_1}));
THEN("vfs initializes and provides expected mount points")
{
auto & vfs = kernel::filesystem::vfs::get();
auto root = vfs.open("/");
auto dev = vfs.open("/dev");
auto information = vfs.open("/information/info_1.txt");
REQUIRE(root != nullptr);
REQUIRE(dev != nullptr);
REQUIRE(information != nullptr);
}
}
GIVEN("three real image files")
{
REQUIRE(std::filesystem::exists(image_path_1));
REQUIRE(std::filesystem::exists(image_path_2));
REQUIRE(std::filesystem::exists(image_path_3));
REQUIRE_NOTHROW(setup_modules_from_img_and_init_vfs({"test_img_module_1", "test_img_module_2", "test_img_module_3"},
{image_path_1, image_path_2, image_path_3}));
auto & vfs = kernel::filesystem::vfs::get();
THEN("vfs initializes first module as root")
{
auto & vfs = kernel::filesystem::vfs::get();
auto info1 = vfs.open("/information/info_1.txt");
auto info2 = vfs.open("/information/info_2.txt");
REQUIRE(info1 != nullptr);
REQUIRE(info2 != nullptr);
}
THEN("second image can be mounted, data retrieved and unmounted again")
{
REQUIRE(vfs.do_mount("/dev/ram16", "/information") == kernel::filesystem::vfs::operation_result::success);
auto mounted_monkey_1 = vfs.open("/information/monkey_house/monkey_1.txt");
REQUIRE(mounted_monkey_1 != nullptr);
REQUIRE(vfs.unmount("/information") == kernel::filesystem::vfs::operation_result::success);
auto unmounted_monkey_1 = vfs.open("/information/monkey_house/monkey_1.txt");
REQUIRE(unmounted_monkey_1 == nullptr);
auto info_1 = vfs.open("/information/info_1.txt");
REQUIRE(info_1 != nullptr);
}
THEN("third image can be mounted in a mounted file system, unmount only if no child mount exists")
{
REQUIRE(vfs.do_mount("/dev/ram16", "/information") == kernel::filesystem::vfs::operation_result::success);
REQUIRE(vfs.do_mount("/dev/ram32", "/information/monkey_house/infrastructure") ==
kernel::filesystem::vfs::operation_result::success);
auto mounted_monkey_1 = vfs.open("/information/monkey_house/monkey_1.txt");
auto mounted_fish1 = vfs.open("/information/monkey_house/infrastructure/enclosures/aquarium/tank_1/fish_1.txt");
REQUIRE(mounted_monkey_1 != nullptr);
REQUIRE(mounted_fish1 != nullptr);
REQUIRE(vfs.unmount("/information") == kernel::filesystem::vfs::operation_result::unmount_failed);
REQUIRE(vfs.unmount("/information/monkey_house/infrastructure") ==
kernel::filesystem::vfs::operation_result::success);
REQUIRE(vfs.unmount("/information") == kernel::filesystem::vfs::operation_result::success);
}
THEN("images can be stacked mounted and correct file system is unmounted again")
{
REQUIRE(vfs.do_mount("/dev/ram16", "/information") == kernel::filesystem::vfs::operation_result::success);
REQUIRE(vfs.do_mount("/dev/ram32", "/information") == kernel::filesystem::vfs::operation_result::success);
auto mounted_tickets = vfs.open("/information/entrance/tickets.txt");
REQUIRE(mounted_tickets != nullptr);
REQUIRE(vfs.unmount("/information") == kernel::filesystem::vfs::operation_result::success);
mounted_tickets = vfs.open("/information/entrance/tickets.txt");
REQUIRE(mounted_tickets == nullptr);
auto mounted_monkey = vfs.open("/information/monkey_house/monkey_1.txt");
REQUIRE(mounted_monkey != nullptr);
}
THEN("mount with null file system fails")
{
REQUIRE(vfs.do_mount("/closed.txt", "/information") ==
kernel::filesystem::vfs::operation_result::invalid_filesystem);
}
THEN("mount with invalid path fails")
{
REQUIRE(vfs.do_mount("/dev/ram16", "") == kernel::filesystem::vfs::operation_result::invalid_path);
REQUIRE(vfs.do_mount("/dev/ram16", "information") == kernel::filesystem::vfs::operation_result::invalid_path);
REQUIRE(vfs.do_mount("/dev/ram16", "/information/") == kernel::filesystem::vfs::operation_result::invalid_path);
}
THEN("mount with non-existent source path fails")
{
REQUIRE(vfs.do_mount("/dev/nonexistent", "/information") ==
kernel::filesystem::vfs::operation_result::non_existent_path);
}
THEN("mount with non-existent mount point fails")
{
REQUIRE(vfs.do_mount("/dev/ram16", "/information/nonexistent") ==
kernel::filesystem::vfs::operation_result::mount_point_not_found);
}
THEN("unmount with invalid path fails")
{
REQUIRE(vfs.unmount("") == kernel::filesystem::vfs::operation_result::invalid_path);
REQUIRE(vfs.unmount("information") == kernel::filesystem::vfs::operation_result::invalid_path);
REQUIRE(vfs.unmount("/information/") == kernel::filesystem::vfs::operation_result::invalid_path);
}
THEN("unmounting non-existent mount point returns expected error code")
{
REQUIRE(vfs.unmount("/information/nonexistent") ==
kernel::filesystem::vfs::operation_result::mount_point_not_found);
}
THEN("a file can be access if . in the path")
{
auto info_1 = vfs.open("/information/./info_1.txt");
REQUIRE(info_1 != nullptr);
}
THEN("a file can be accessed within the same mount if path contains .. ")
{
auto info_1 = vfs.open("/archiv/../information/info_1.txt");
REQUIRE(info_1 != nullptr);
auto img = vfs.open("/archiv/../information/../archiv/2024.img");
REQUIRE(img != nullptr);
}
THEN("a file can be accessed over multiple mounts if path contains .. or . ")
{
REQUIRE(vfs.do_mount("/dev/ram16", "/information") == kernel::filesystem::vfs::operation_result::success);
auto img = vfs.open("/information/monkey_house/caretaker/../../../archiv/2024.img");
REQUIRE(img != nullptr);
auto dev_32 = vfs.open("/information/monkey_house/caretaker/../../../dev/ram32");
REQUIRE(dev_32 != nullptr);
auto water = vfs.open("/information/./monkey_house/infrastructure/water.txt");
REQUIRE(water != nullptr);
}
THEN("a file can be accessed over multiple mounts (device and file) if path contains .. ")
{
REQUIRE(vfs.do_mount("/dev/ram16", "/information") == kernel::filesystem::vfs::operation_result::success);
REQUIRE(vfs.do_mount("/archiv/2024.img", "/information/monkey_house/infrastructure") ==
kernel::filesystem::vfs::operation_result::success);
auto pig_1 = vfs.open("/information/monkey_house/infrastructure/stable/pig_1.txt");
REQUIRE(pig_1 != nullptr);
auto isabelle =
vfs.open("/information/monkey_house/infrastructure/stable/../../../monkey_house/caretaker/isabelle.txt");
REQUIRE(isabelle != nullptr);
auto closed = vfs.open("/information/monkey_house/infrastructure/stable/../../../../closed.txt");
REQUIRE(closed != nullptr);
}
}
GIVEN("A real image file containing as filesystem formatted files")
{
REQUIRE(std::filesystem::exists(image_path_1));
REQUIRE_NOTHROW(setup_modules_from_img_and_init_vfs({"test_img_module_1"}, {image_path_1}));
THEN("the file-filesystem in the image can be mounted, files can be read and unmounted again")
{
auto & vfs = kernel::filesystem::vfs::get();
REQUIRE(vfs.do_mount("/archiv/2024.img", "/information") == kernel::filesystem::vfs::operation_result::success);
auto info_1 = vfs.open("/information/info_1.txt");
REQUIRE(info_1 == nullptr);
auto dentry = vfs.open("/information/sheep_1.txt");
REQUIRE(dentry != nullptr);
auto sheep_1_ofd = kstd::make_shared<kernel::filesystem::open_file_descriptor>(dentry->get_inode());
kstd::vector<std::byte> buffer(7);
auto bytes_read = sheep_1_ofd->read(buffer.data(), buffer.size());
std::string_view buffer_as_str{reinterpret_cast<char *>(buffer.data()), bytes_read};
REQUIRE(buffer_as_str == "sheep_1");
REQUIRE(vfs.unmount("/information") == kernel::filesystem::vfs::operation_result::success);
auto unmounted_sheep_1 = vfs.open("/information/sheep_1.txt");
REQUIRE(unmounted_sheep_1 == nullptr);
}
THEN("the file-filesystem in the image can be mounted and in this filesystem can another file-filesystem be "
"mounted, files can be read and unmounted again")
{
auto & vfs = kernel::filesystem::vfs::get();
REQUIRE(vfs.do_mount("/archiv/2024.img", "/information") == kernel::filesystem::vfs::operation_result::success);
REQUIRE(vfs.do_mount("/archiv/2025.img", "/information/stable") ==
kernel::filesystem::vfs::operation_result::success);
auto sheep_1 = vfs.open("/information/sheep_1.txt");
auto goat_1 = vfs.open("/information/stable/petting_zoo/goat_1.txt");
REQUIRE(sheep_1 != nullptr);
REQUIRE(goat_1 != nullptr);
auto sheep_1_ofd = kstd::make_shared<kernel::filesystem::open_file_descriptor>(sheep_1->get_inode());
auto goat_1_ofd = kstd::make_shared<kernel::filesystem::open_file_descriptor>(goat_1->get_inode());
kstd::vector<std::byte> sheep_buffer(7);
auto bytes_read = sheep_1_ofd->read(sheep_buffer.data(), sheep_buffer.size());
std::string_view buffer_as_str{reinterpret_cast<char *>(sheep_buffer.data()), bytes_read};
REQUIRE(buffer_as_str == "sheep_1");
kstd::vector<std::byte> goat_buffer(6);
bytes_read = goat_1_ofd->read(goat_buffer.data(), goat_buffer.size());
buffer_as_str = std::string_view{reinterpret_cast<char *>(goat_buffer.data()), bytes_read};
REQUIRE(buffer_as_str == "goat_1");
REQUIRE(vfs.unmount("/information") == kernel::filesystem::vfs::operation_result::unmount_failed);
REQUIRE(vfs.unmount("/information/stable") == kernel::filesystem::vfs::operation_result::success);
auto unmounted_goat_1 = vfs.open("/information/stable/petting_zoo/goat_1.txt");
REQUIRE(unmounted_goat_1 == nullptr);
auto still_mounted_sheep_1 = vfs.open("/information/sheep_1.txt");
REQUIRE(still_mounted_sheep_1 != nullptr);
REQUIRE(vfs.unmount("/information") == kernel::filesystem::vfs::operation_result::success);
auto unmounted_sheep_1 = vfs.open("/information/sheep_1.txt");
REQUIRE(unmounted_sheep_1 == nullptr);
}
}
GIVEN("one real image files, containing symbolic links")
{
REQUIRE(std::filesystem::exists(image_path_1));
REQUIRE_NOTHROW(setup_modules_from_img_and_init_vfs({"test_img_module_1"}, {image_path_1}));
THEN("file can be opened through absolute symbolic link")
{
auto & vfs = kernel::filesystem::vfs::get();
auto info_1 = vfs.open("/symlinks/info_1_absolute");
REQUIRE(info_1 != nullptr);
}
THEN("file can be opened through relative symbolic link")
{
auto & vfs = kernel::filesystem::vfs::get();
auto info_1 = vfs.open("/symlinks/info_1_relative");
REQUIRE(info_1 != nullptr);
}
}
}
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