esp-idf/tools/unit-test-app/components/test_utils/include/test_utils.h
2020-03-09 13:41:56 +01:00

280 lines
9.3 KiB
C

// Copyright 2015-2018 Espressif Systems (Shanghai) PTE LTD
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#pragma once
// Utilities for esp-idf unit tests
#include <stdint.h>
#include <esp_partition.h>
#include "sdkconfig.h"
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
/* include performance pass standards header file */
#include "idf_performance.h"
/* For performance check with unity test on IDF */
/* These macros should only be used with ESP-IDF.
* To use performance check, we need to first define pass standard in idf_performance.h.
*/
//macros call this to expand an argument instead of directly converting into str
#define PERFORMANCE_STR(s) #s
//macros call this to contact strings after expanding them
#define PERFORMANCE_CON(a, b) _PERFORMANCE_CON(a, b)
#define _PERFORMANCE_CON(a, b) a##b
#define TEST_PERFORMANCE_LESS_THAN(name, value_fmt, value) do { \
printf("[Performance]["PERFORMANCE_STR(name)"]: "value_fmt"\n", value); \
TEST_ASSERT(value < PERFORMANCE_CON(IDF_PERFORMANCE_MAX_, name)); \
} while(0)
#define TEST_PERFORMANCE_GREATER_THAN(name, value_fmt, value) do { \
printf("[Performance]["PERFORMANCE_STR(name)"]: "value_fmt"\n", value); \
TEST_ASSERT(value > PERFORMANCE_CON(IDF_PERFORMANCE_MIN_, name)); \
} while(0)
/* @brief macro to print IDF performance
* @param mode : performance item name. a string pointer.
* @param value_fmt: print format and unit of the value, for example: "%02fms", "%dKB"
* @param value : the performance value.
*/
#define IDF_LOG_PERFORMANCE(item, value_fmt, value) \
printf("[Performance][%s]: "value_fmt"\n", item, value)
/* Some definitions applicable to Unity running in FreeRTOS */
#define UNITY_FREERTOS_PRIORITY CONFIG_UNITY_FREERTOS_PRIORITY
#define UNITY_FREERTOS_CPU CONFIG_UNITY_FREERTOS_CPU
#define UNITY_FREERTOS_STACK_SIZE CONFIG_UNITY_FREERTOS_STACK_SIZE
/* Return the 'flash_test' custom data partition (type 0x55)
defined in the custom partition table.
*/
const esp_partition_t *get_test_data_partition(void);
/**
* @brief Initialize reference clock
*
* Reference clock provides timestamps at constant 1 MHz frequency, even when
* the APB frequency is changing.
*/
void ref_clock_init(void);
/**
* @brief Deinitialize reference clock
*/
void ref_clock_deinit(void);
/**
* @brief Get reference clock timestamp
* @return number of microseconds since the reference clock was initialized
*/
uint64_t ref_clock_get(void);
/**
* @brief Entry point of the test application
*
* Starts Unity test runner in a separate task and returns.
*/
void test_main(void);
/**
* @brief Reset automatic leak checking which happens in unit tests.
*
* Updates recorded "before" free memory values to the free memory values
* at time of calling. Resets leak checker if tracing is enabled in
* config.
*
* This can be called if a test case does something which allocates
* memory on first use, for example.
*
* @note Use with care as this can mask real memory leak problems.
*/
void unity_reset_leak_checks(void);
/**
* @brief Call this function from a test case which requires TCP/IP or
* LWIP functionality.
*
* @note This should be the first function the test case calls, as it will
* allocate memory on first use (and also reset the test case leak checker).
*/
void test_case_uses_tcpip(void);
/**
* @brief wait for signals with parameters.
*
* for multiple devices test cases, DUT might need to wait for other DUTs before continue testing.
* As all DUTs are independent, need user (or test script) interaction to make test synchronized.
*
* Here we provide signal functions for this.
* For example, we're testing GPIO, DUT1 has one pin connect to with DUT2.
* DUT2 will output high level and then DUT1 will read input.
* DUT1 should call `unity_wait_for_signal("output high level");` before it reads input.
* DUT2 should call `unity_send_signal("output high level");` after it finished setting output high level.
* According to the console logs:
*
* DUT1 console:
*
* ```
* Waiting for signal: [output high level]!
* Please press "Enter" key to once any board send this signal.
* ```
*
* DUT2 console:
*
* ```
* Send signal: [output high level]!
* ```
*
* Then we press Enter key on DUT1's console, DUT1 starts to read input and then test success.
*
* Another example, we have 2 DUTs in multiple devices test, and DUT1 need to get DUT2's mac address to perform BT connection.
* DUT1 should call `unity_wait_for_signal_param("dut2 mac address", mac, 19);` to wait for DUT2's mac address.
* DUT2 should call `unity_send_signal_param("dut2 mac address", "10:20:30:40:50:60");` to send to DUT1 its mac address.
* According to the console logs:
*
* DUT1 console:
*
* ```
* Waiting for signal: [dut2 mac address]!
* Please input parameter value from any board send this signal and press "Enter" key.
* ```
*
* DUT2 console:
*
* ```
* Send signal: [dut2 mac address][10:20:30:40:50:60]!
* ```
*
* @param signal_name signal name which DUT expected to wait before proceed testing
* @param parameter_buf buffer to receive parameter
* @param buf_len length of parameter_buf.
* Currently we have a limitation that it will write 1 extra byte at the end of string.
* We need to use a buffer with 2 bytes longer than actual string length.
*/
void unity_wait_for_signal_param(const char* signal_name, char *parameter_buf, uint8_t buf_len);
/**
* @brief wait for signals.
*
* @param signal_name signal name which DUT expected to wait before proceed testing
*/
static inline void unity_wait_for_signal(const char* signal_name)
{
unity_wait_for_signal_param(signal_name, NULL, 0);
}
/**
* @brief DUT send signal and pass parameter to other devices.
*
* @param signal_name signal name which DUT send once it finished preparing.
* @param parameter a string to let remote device to receive.
*/
void unity_send_signal_param(const char* signal_name, const char *parameter);
/**
* @brief DUT send signal with parameter.
*
* @param signal_name signal name which DUT send once it finished preparing.
*/
static inline void unity_send_signal(const char* signal_name)
{
unity_send_signal_param(signal_name, NULL);
}
/**
* @brief convert mac string to mac address
*
* @param mac_str MAC address string with format "xx:xx:xx:xx:xx:xx"
* @param[out] mac_addr store converted MAC address
*/
bool unity_util_convert_mac_from_string(const char* mac_str, uint8_t *mac_addr);
/**
* @brief Leak for components
*/
typedef enum {
COMP_LEAK_GENERAL = 0, /**< Leak by default */
COMP_LEAK_LWIP, /**< Leak for LWIP */
COMP_LEAK_NVS, /**< Leak for NVS */
COMP_LEAK_ALL, /**< Use for getting the summary leak level */
} esp_comp_leak_t;
/**
* @brief Type of leak
*/
typedef enum {
TYPE_LEAK_WARNING = 0, /**< Warning level of leak */
TYPE_LEAK_CRITICAL, /**< Critical level of leak */
TYPE_LEAK_MAX, /**< Max number of leak levels */
} esp_type_leak_t;
/**
* @brief Set a leak level for the required type and component.
*
* @param[in] leak_level Level of leak
* @param[in] type Type of leak
* @param[in] component Name of component
*
* return ESP_OK: Successful.
* ESP_ERR_INVALID_ARG: Invalid argument.
*/
esp_err_t test_utils_set_leak_level(size_t leak_level, esp_type_leak_t type, esp_comp_leak_t component);
/**
* @brief Get a leak level for the required type and component.
*
* @param[in] type Type of leak.
* @param[in] component Name of component. If COMP_LEAK_ALL, then the level will be summarized for all components.
* return Leak level
*/
size_t test_utils_get_leak_level(esp_type_leak_t type, esp_comp_leak_t component);
typedef struct test_utils_exhaust_memory_record_s *test_utils_exhaust_memory_rec;
/**
* Limit the largest free block of memory with a particular capability set to
* 'limit' bytes (meaning an allocation of 'limit' should succeed at least once,
* but any allocation of more bytes will fail.)
*
* Returns a record pointer which needs to be passed back in to test_utils_free_exhausted_memory
* before the test completes, to avoid a major memory leak.
*
* @param caps Capabilities of memory to exhause
* @param limit The size to limit largest free block to
* @return Record pointer to pass to test_utils_free_exhausted_memory() once done
*/
test_utils_exhaust_memory_rec test_utils_exhaust_memory(uint32_t caps, size_t limit);
/**
* Call to free memory which was taken up by test_utils_exhaust_memory() call
*
* @param rec Result previously returned from test_utils_exhaust_memory()
*/
void test_utils_free_exhausted_memory(test_utils_exhaust_memory_rec rec);
/**
* @brief Delete task ensuring dynamic memory (for stack, tcb etc.) gets freed up immediately
*
* @param[in] thandle Handle of task to be deleted (should not be NULL or self handle)
*/
void test_utils_task_delete(TaskHandle_t thandle);