RASCSI/cpp/test/test_shared.cpp

148 lines
4.7 KiB
C++

//---------------------------------------------------------------------------
//
// SCSI Target Emulator RaSCSI Reloaded
// for Raspberry Pi
//
// Copyright (C) 2022 Uwe Seimet
//
//---------------------------------------------------------------------------
#include "test_shared.h"
#include "controllers/controller_manager.h"
#include "mocks.h"
#include "shared/rascsi_exceptions.h"
#include "shared/rascsi_version.h"
#include <filesystem>
#include <sstream>
#include <unistd.h>
#include <vector>
using namespace std;
using namespace filesystem;
// Inlude the process id in the temp file path so that multiple instances of the test procedures
// could run on the same host.
const path test_data_temp_path(temp_directory_path() /
path(fmt::format("rascsi-test-{}",
getpid()))); // NOSONAR Publicly writable directory is fine here
shared_ptr<PrimaryDevice> CreateDevice(PbDeviceType type, MockAbstractController &controller, const string &extension)
{
DeviceFactory device_factory;
auto device = device_factory.CreateDevice(type, 0, extension);
unordered_map<string, string> params;
device->Init(params);
controller.AddDevice(device);
return device;
}
void TestInquiry(PbDeviceType type, device_type t, scsi_level l, const string &ident, int additional_length,
bool removable, const string &extension)
{
auto bus = make_shared<MockBus>();
auto controller_manager = make_shared<ControllerManager>(*bus);
auto controller = make_shared<NiceMock<MockAbstractController>>(controller_manager, 0);
auto device = CreateDevice(type, *controller, extension);
auto &cmd = controller->GetCmd();
// ALLOCATION LENGTH
cmd[4] = 255;
EXPECT_CALL(*controller, DataIn());
device->Dispatch(scsi_command::eCmdInquiry);
const vector<uint8_t> &buffer = controller->GetBuffer();
EXPECT_EQ(t, static_cast<device_type>(buffer[0]));
EXPECT_EQ(removable ? 0x80 : 0x00, buffer[1]);
EXPECT_EQ(l, static_cast<scsi_level>(buffer[2]));
EXPECT_EQ(l > scsi_level::SCSI_2 ? scsi_level::SCSI_2 : l, static_cast<scsi_level>(buffer[3]));
EXPECT_EQ(additional_length, buffer[4]);
string product_data;
if (ident.size() == 24) {
ostringstream s;
s << ident << setw(2) << setfill('0') << rascsi_major_version << rascsi_minor_version;
product_data = s.str();
} else {
product_data = ident;
}
EXPECT_TRUE(!memcmp(product_data.c_str(), &buffer[8], 28));
}
pair<int, path> OpenTempFile()
{
const string filename =
string(test_data_temp_path) + "/rascsi_test-XXXXXX"; // NOSONAR Publicly writable directory is fine here
vector<char> f(filename.begin(), filename.end());
f.push_back(0);
create_directories(path(filename).parent_path());
const int fd = mkstemp(f.data());
EXPECT_NE(-1, fd) << "Couldn't create temporary file '" << f.data() << "'";
return make_pair(fd, path(f.data()));
}
path CreateTempFile(int size)
{
const auto [fd, filename] = OpenTempFile();
vector<char> data(size);
const size_t count = write(fd, data.data(), data.size());
close(fd);
EXPECT_EQ(count, data.size()) << "Couldn't create temporary file '" << string(filename) << "'";
return path(filename);
}
void CreateTempFileWithData(string filename, vector<uint8_t> &data)
{
path new_filename = test_data_temp_path;
new_filename += path(filename);
create_directories(new_filename.parent_path());
FILE *fp = fopen(new_filename.c_str(), "wb");
if (fp == nullptr) {
printf("ERROR: Unable to open file %s\n", new_filename.c_str());
return;
}
size_t size_written = fwrite(&data[0], sizeof(uint8_t), data.size(), fp);
if (size_written != sizeof(vector<uint8_t>::value_type) * data.size()) {
printf("Expected to write %zu bytes, but only wrote %zu to %s", size_written,
sizeof(vector<uint8_t>::value_type) * data.size(), filename.c_str());
}
fclose(fp);
}
void DeleteTempFile(string filename)
{
path temp_file = test_data_temp_path;
temp_file += path(filename);
remove(temp_file);
}
void CleanupAllTempFiles()
{
remove_all(test_data_temp_path);
}
int GetInt16(const vector<byte> &buf, int offset)
{
assert(buf.size() > static_cast<size_t>(offset) + 1);
return (to_integer<int>(buf[offset]) << 8) | to_integer<int>(buf[offset + 1]);
}
uint32_t GetInt32(const vector<byte> &buf, int offset)
{
assert(buf.size() > static_cast<size_t>(offset) + 3);
return (to_integer<uint32_t>(buf[offset]) << 24) | (to_integer<uint32_t>(buf[offset + 1]) << 16) |
(to_integer<uint32_t>(buf[offset + 2]) << 8) | to_integer<uint32_t>(buf[offset + 3]);
}