libzmq/tests/testutil_unity.hpp

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#pragma once
/* SPDX-License-Identifier: MPL-2.0 */
#include "../include/zmq.h"
#include "testutil.hpp"
#include <unity.h>
// Internal helper functions that are not intended to be directly called from
// tests. They must be declared in the header since they are used by macros.
int test_assert_success_message_errno_helper (int rc_,
const char *msg_,
const char *expr_,
int line);
int test_assert_success_message_raw_errno_helper (
int rc_, const char *msg_, const char *expr_, int line, bool zero_ = false);
int test_assert_success_message_raw_zero_errno_helper (int rc_,
const char *msg_,
const char *expr_,
int line);
int test_assert_failure_message_raw_errno_helper (
int rc_, int expected_errno_, const char *msg_, const char *expr_, int line);
/////////////////////////////////////////////////////////////////////////////
// Macros extending Unity's TEST_ASSERT_* macros in a similar fashion.
/////////////////////////////////////////////////////////////////////////////
// For TEST_ASSERT_SUCCESS_ERRNO, TEST_ASSERT_SUCCESS_MESSAGE_ERRNO and
// TEST_ASSERT_FAILURE_ERRNO, 'expr' must be an expression evaluating
// to a result in the style of a libzmq API function, i.e. an integer which
// is non-negative in case of success, and -1 in case of a failure, and sets
// the value returned by zmq_errno () to the error code.
// TEST_ASSERT_SUCCESS_RAW_ERRNO and TEST_ASSERT_FAILURE_RAW_ERRNO are similar,
// but used with the native socket API functions, and expect that the error
// code can be retrieved in the native way (i.e. WSAGetLastError on Windows,
// and errno otherwise).
// Asserts that the libzmq API 'expr' is successful. In case of a failure, the
// assertion message includes the literal 'expr', the error number as
// determined by zmq_errno(), and the additional 'msg'.
// In case of success, the result of the macro is the result of 'expr'.
#define TEST_ASSERT_SUCCESS_MESSAGE_ERRNO(expr, msg) \
test_assert_success_message_errno_helper (expr, msg, #expr, __LINE__)
// Asserts that the libzmq API 'expr' is successful. In case of a failure, the
// assertion message includes the literal 'expr' and the error code.
// A typical use would be:
// TEST_ASSERT_SUCCESS_ERRNO (zmq_connect (socket, endpoint));
// In case of success, the result of the macro is the result of 'expr'.
//
// If an additional message should be displayed in case of a failure, use
// TEST_ASSERT_SUCCESS_MESSAGE_ERRNO.
#define TEST_ASSERT_SUCCESS_ERRNO(expr) \
test_assert_success_message_errno_helper (expr, NULL, #expr, __LINE__)
// Asserts that the socket API 'expr' is successful. In case of a failure, the
// assertion message includes the literal 'expr' and the error code.
// A typical use would be:
// TEST_ASSERT_SUCCESS_RAW_ERRNO (send (fd, buffer, 64, 0));
// In case of success, the result of the macro is the result of 'expr'.
// Success is strictly defined by a return value different from -1, as opposed
// to checking that it is 0, like TEST_ASSERT_FAILURE_RAW_ZERO_ERRNO does.
#define TEST_ASSERT_SUCCESS_RAW_ERRNO(expr) \
test_assert_success_message_raw_errno_helper (expr, NULL, #expr, __LINE__)
// Asserts that the socket API 'expr' is successful. In case of a failure, the
// assertion message includes the literal 'expr' and the error code.
// A typical use would be:
// TEST_ASSERT_SUCCESS_RAW_ZERO_ERRNO (send (fd, buffer, 64, 0));
// In case of success, the result of the macro is the result of 'expr'.
// Success is strictly defined by a return value of 0, as opposed to checking
// that it is not -1, like TEST_ASSERT_FAILURE_RAW_ERRNO does.
#define TEST_ASSERT_SUCCESS_RAW_ZERO_ERRNO(expr) \
test_assert_success_message_raw_zero_errno_helper (expr, NULL, #expr, \
__LINE__)
// Asserts that the socket API 'expr' is not successful, and the error code is
// 'error_code'. In case of an unexpected succces, or a failure with an
// unexpected error code, the assertion message includes the literal 'expr'
// and, in case of a failure, the actual error code.
#define TEST_ASSERT_FAILURE_RAW_ERRNO(error_code, expr) \
test_assert_failure_message_raw_errno_helper (expr, error_code, NULL, \
#expr, __LINE__)
// Asserts that the libzmq API 'expr' is not successful, and the error code is
// 'error_code'. In case of an unexpected succces, or a failure with an
// unexpected error code, the assertion message includes the literal 'expr'
// and, in case of a failure, the actual error code.
#define TEST_ASSERT_FAILURE_ERRNO(error_code, expr) \
{ \
int _rc = (expr); \
TEST_ASSERT_EQUAL_INT (-1, _rc); \
TEST_ASSERT_EQUAL_INT (error_code, errno); \
}
/////////////////////////////////////////////////////////////////////////////
// Utility functions for testing sending and receiving.
/////////////////////////////////////////////////////////////////////////////
// Sends a string via a libzmq socket, and expects the operation to be
// successful (the meaning of which depends on the socket type and configured
// options, and might include dropping the message). Otherwise, a Unity test
// assertion is triggered.
// 'socket_' must be the libzmq socket to use for sending.
// 'str_' must be a 0-terminated string.
// 'flags_' are as documented by the zmq_send function.
void send_string_expect_success (void *socket_, const char *str_, int flags_);
// Receives a message via a libzmq socket, and expects the operation to be
// successful, and the message to be a given string. Otherwise, a Unity test
// assertion is triggered.
// 'socket_' must be the libzmq socket to use for receiving.
// 'str_' must be a 0-terminated string.
// 'flags_' are as documented by the zmq_recv function.
void recv_string_expect_success (void *socket_, const char *str_, int flags_);
// Sends a byte array via a libzmq socket, and expects the operation to be
// successful (the meaning of which depends on the socket type and configured
// options, and might include dropping the message). Otherwise, a Unity test
// assertion is triggered.
// 'socket_' must be the libzmq socket to use for sending.
// 'array_' must be a C uint8_t array. The array size is automatically
// determined via template argument deduction.
// 'flags_' are as documented by the zmq_send function.
template <size_t SIZE>
void send_array_expect_success (void *socket_,
const uint8_t (&array_)[SIZE],
int flags_)
{
const int rc = zmq_send (socket_, array_, SIZE, flags_);
TEST_ASSERT_EQUAL_INT (static_cast<int> (SIZE), rc);
}
// Receives a message via a libzmq socket, and expects the operation to be
// successful, and the message to be a given byte array. Otherwise, a Unity
// test assertion is triggered.
// 'socket_' must be the libzmq socket to use for receiving.
// 'array_' must be a C uint8_t array. The array size is automatically
// determined via template argument deduction.
// 'flags_' are as documented by the zmq_recv function.
template <size_t SIZE>
void recv_array_expect_success (void *socket_,
const uint8_t (&array_)[SIZE],
int flags_)
{
char buffer[255];
TEST_ASSERT_LESS_OR_EQUAL_MESSAGE (sizeof (buffer), SIZE,
"recv_string_expect_success cannot be "
"used for strings longer than 255 "
"characters");
const int rc = TEST_ASSERT_SUCCESS_ERRNO (
zmq_recv (socket_, buffer, sizeof (buffer), flags_));
TEST_ASSERT_EQUAL_INT (static_cast<int> (SIZE), rc);
TEST_ASSERT_EQUAL_UINT8_ARRAY (array_, buffer, SIZE);
}
/////////////////////////////////////////////////////////////////////////////
// Utility function for handling a test libzmq context, that is set up and
// torn down for each Unity test case, such that a clean context is available
// for each test case, and some consistency checks can be performed.
/////////////////////////////////////////////////////////////////////////////
// Use this is an test executable to perform a default setup and teardown of
// the test context, which is appropriate for many libzmq test cases.
#define SETUP_TEARDOWN_TESTCONTEXT \
void setUp () \
{ \
setup_test_context (); \
} \
void tearDown () \
{ \
teardown_test_context (); \
}
// The maximum number of sockets that can be managed by the test context.
#define MAX_TEST_SOCKETS 128
// Expected to be called during Unity's setUp function.
void setup_test_context ();
// Returns the test context, e.g. to create sockets in another thread using
// zmq_socket, or set context options.
void *get_test_context ();
// Expected to be called during Unity's tearDown function. Checks that all
// sockets created via test_context_socket have been properly closed using
// test_context_socket_close or test_context_socket_close_zero_linger, and generates a warning otherwise.
void teardown_test_context ();
// Creates a libzmq socket on the test context, and tracks its lifecycle.
// You MUST use test_context_socket_close or test_context_socket_close_zero_linger
// to close a socket created via this function, otherwise undefined behaviour
// will result.
// CAUTION: this function is not thread-safe, and may only be used from the
// main thread.
void *test_context_socket (int type_);
// Closes a socket created via test_context_socket.
// CAUTION: this function is not thread-safe, and may only be used from the
// main thread.
void *test_context_socket_close (void *socket_);
// Closes a socket created via test_context_socket after setting its linger
// timeout to 0.
// CAUTION: this function is not thread-safe, and may only be used from the
// main thread.
void *test_context_socket_close_zero_linger (void *socket_);
/////////////////////////////////////////////////////////////////////////////
// Utility function for handling wildcard binds.
/////////////////////////////////////////////////////////////////////////////
// All function binds a socket to some wildcard address, and retrieve the bound
// endpoint via the ZMQ_LAST_ENDPOINT socket option to a given buffer.
// Triggers a Unity test assertion in case of a failure (including the buffer
// being too small for the resulting endpoint string).
// Binds to an explicitly given (wildcard) address.
// TODO redesign such that this function is not necessary to be exposed, but
// the protocol to use is rather specified via an enum value
void test_bind (void *socket_,
const char *bind_address_,
char *my_endpoint_,
size_t len_);
// Binds to a tcp endpoint using the ipv4 or ipv6 loopback wildcard address.
void bind_loopback (void *socket_, int ipv6_, char *my_endpoint_, size_t len_);
typedef void (*bind_function_t) (void *socket_,
char *my_endpoint_,
size_t len_);
// Binds to a tcp endpoint using the ipv4 loopback wildcard address.
void bind_loopback_ipv4 (void *socket_, char *my_endpoint_, size_t len_);
// Binds to a tcp endpoint using the ipv6 loopback wildcard address.
void bind_loopback_ipv6 (void *socket_, char *my_endpoint_, size_t len_);
// Binds to an ipc endpoint using the ipc wildcard address.
// Note that the returned address cannot be reused to bind a second socket.
// If you need to do this, use make_random_ipc_endpoint instead.
void bind_loopback_ipc (void *socket_, char *my_endpoint_, size_t len_);
// Binds to an ipc endpoint using the tipc wildcard address.
void bind_loopback_tipc (void *socket_, char *my_endpoint_, size_t len_);
#if defined(ZMQ_HAVE_IPC)
// utility function to create a random IPC endpoint, similar to what a ipc://*
// wildcard binding does, but in a way it can be reused for multiple binds
// TODO also add a len parameter here
void make_random_ipc_endpoint (char *out_endpoint_);
#endif