takashi kadono
/
Nucleo446_SSD1331
Color Oled(SSD1331) connect to STMicroelectronics Nucleo-F466
mbed-os/hal/crc_api.h
- Committer:
- kadonotakashi
- Date:
- 2018-10-11
- Revision:
- 3:f3764f852aa8
- Parent:
- 0:8fdf9a60065b
File content as of revision 3:f3764f852aa8:
/** \addtogroup hal */ /** @{*/ /* mbed Microcontroller Library * Copyright (c) 2018 ARM Limited * * 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. */ #ifndef MBED_CRC_HAL_API_H #define MBED_CRC_HAL_API_H #include <stdbool.h> #include <stddef.h> #include <stdint.h> /** CRC Polynomial value * * Different polynomial values supported */ typedef enum crc_polynomial { POLY_OTHER = 0, POLY_8BIT_CCITT = 0x07, // x8+x2+x+1 POLY_7BIT_SD = 0x9, // x7+x3+1; POLY_16BIT_CCITT = 0x1021, // x16+x12+x5+1 POLY_16BIT_IBM = 0x8005, // x16+x15+x2+1 POLY_32BIT_ANSI = 0x04C11DB7, // x32+x26+x23+x22+x16+x12+x11+x10+x8+x7+x5+x4+x2+x+1 POLY_32BIT_REV_ANSI = 0xEDB88320 } crc_polynomial_t; typedef struct crc_mbed_config { /** CRC Polynomial. Example polynomial: 0x21 = 0010_0011 = x^5+x+1 */ uint32_t polynomial; /** CRC Bit Width */ uint32_t width; /** Initial seed value for the computation. */ uint32_t initial_xor; /** Final xor value for the computation. */ uint32_t final_xor; /** Reflect bits on input. */ bool reflect_in; /** Reflect bits in final result before returning. */ bool reflect_out; } crc_mbed_config_t; #ifdef DEVICE_CRC #ifdef __cplusplus extern "C" { #endif /** * \defgroup hal_crc Hardware CRC * * The Hardware CRC HAL API provides a low-level interface to the Hardware CRC * module of a target platform. * * # Defined behaviour * * * Function hal_crc_is_supported() returns true if platform supports hardware * CRC for the given polynomial/width - verified by test ::crc_is_supported_test. * * Function hal_crc_is_supported() returns false if platform does not support hardware * CRC for the given polynomial/width - verified by test ::crc_is_supported_test. * * Function hal_crc_is_supported() returns false if given pointer to configuration * structure is undefined (NULL) - verified by test ::crc_is_supported_invalid_param_test. * * If CRC module does not support one of the following settings: initial_xor, final_xor * reflect_in, reflect_out, then these operations should be handled by the driver * - Verified by test ::crc_calc_single_test. * * Platform which supports hardware CRC must be able to handle at least one of the predefined * polynomial/width configurations that can be constructed in the MbedCRC class: POLY_8BIT_CCITT, * POLY_7BIT_SD, POLY_16BIT_CCITT, POLY_16BIT_IBM, POLY_32BIT_ANSI * - verified by test ::crc_is_supported_test, ::crc_calc_single_test. * * Function hal_crc_compute_partial_start() configures CRC module with the given configuration * - Verified by test ::crc_calc_single_test. * * Calling hal_crc_compute_partial_start() without finalising the * CRC calculation overrides the current configuration - Verified by test ::crc_reconfigure_test. * * Function hal_crc_compute_partial() writes data to the CRC module - verified by test ::crc_calc_single_test. * * Function hal_crc_compute_partial() can be call multiple times in succession in order to * provide additional data to CRC module - verified by test ::crc_calc_multi_test. * * Function hal_crc_compute_partial() does nothing if pointer to buffer is undefined or * data length is equal to 0 - verified by test ::crc_compute_partial_invalid_param_test. * * Function hal_crc_get_result() returns the checksum result from the CRC module * - verified by tests ::crc_calc_single_test, ::crc_calc_multi_test, ::crc_reconfigure_test. * * # Undefined behaviour * * * Calling hal_crc_compute_partial_start() function with invalid (unsupported) polynomial. * * Calling hal_crc_compute_partial() or hal_crc_get_result() functions before hal_crc_compute_partial_start(). * * Calling hal_crc_get_result() function multiple times. * * # Non-functional requirements * * * CRC configuration provides the following settings: * * polynomial - CRC Polynomial, * * width - CRC bit width, * * initial_xor - seed value for the computation, * * final_xor - final xor value for the computation, * * reflect_in - reflect bits on input, * * reflect_out - reflect bits in final result before returning. * * # Potential bugs * * @{ */ /** * \defgroup hal_crc_tests crc hal tests * The crc HAL tests ensure driver conformance to defined behaviour. * * To run the crc hal tests use the command: * * mbed test -t <toolchain> -m <target> -n tests-mbed_hal-crc* * */ /** Determine if the current platform supports hardware CRC for given polynomial * * The purpose of this function is to inform the CRC Platform API whether the * current platform has a hardware CRC module and that it can support the * requested polynomial. * * Supported polynomials are restricted to the named polynomials that can be * constructed in the MbedCRC class, POLY_8BIT_CCITT, POLY_7BIT_SD, * POLY_16BIT_CCITT, POLY_16BIT_IBM and POLY_32BIT_ANSI. * * The current platform must support the given polynomials default parameters * in order to return a true response. These include: reflect in, reflect out, * initial xor and final xor. For example, POLY_32BIT_ANSI requires an initial * and final xor of 0xFFFFFFFF, and reflection of both input and output. If any * of these settings cannot be configured, the polynomial is not supported. * * This function is thread safe; it safe to call from multiple contexts if * required. * * \param config Contains CRC configuration parameters for initializing the * hardware CRC module. For example, polynomial and initial seed * values. * * \return True if running if the polynomial is supported, false if not. */ bool hal_crc_is_supported(const crc_mbed_config_t *config); /** Initialize the hardware CRC module with the given polynomial * * After calling this function, the CRC HAL module is ready to receive data * using the hal_crc_compute_partial() function. The CRC module on the board * is configured internally with the specified configuration and is ready * to receive data. * * The platform configures itself based on the default configuration * parameters of the input polynomial. * * This function must be called before calling hal_crc_compute_partial(). * * This function must be called with a valid polynomial supported by the * platform. The polynomial must be checked for support using the * hal_crc_is_supported() function. * * Calling hal_crc_compute_partial_start() multiple times without finalizing the * CRC calculation with hal_crc_get_result() overrides the current * configuration and state, and the intermediate result of the computation is * lost. * * This function is not thread safe. A CRC calculation must not be started from * two different threads or contexts at the same time; calling this function * from two different contexts may lead to configurations being overwritten and * results being lost. * * \param config Contains CRC configuration parameters for initializing the * hardware CRC module. For example, polynomial and initial seed * values. */ void hal_crc_compute_partial_start(const crc_mbed_config_t *config); /** Writes data to the current CRC module. * * Writes input data buffer bytes to the CRC data register. The CRC module * must interpret the data as an array of bytes. * * The final transformations are not applied to the data; the CRC module must * retain the intermediate result so that additional calls to this function * can be made, appending the additional data to the calculation. * * To obtain the final result of the CRC calculation, hal_crc_get_result() is * called to apply the final transformations to the data. * * If the function is passed an undefined pointer, or the size of the buffer is * specified to be 0, this function does nothing and returns. * * This function can be called multiple times in succession. This can be used * to calculate the CRC result of streamed data. * * This function is not thread safe. There is only one instance of the CRC * module active at a time. Calling this function from multiple contexts * appends different data to the same, single instance of the module, which causes an * erroneous value to be calculated. * * \param data Input data stream to be written into the CRC calculation * \param size Size of the data stream in bytes */ void hal_crc_compute_partial(const uint8_t *data, const size_t size); /* Reads the checksum result from the CRC module. * * Reads the final checksum result for the final checksum value. The returned * value is cast as an unsigned 32-bit integer. The actual size of the returned * result depends on the polynomial used to configure the CRC module. * * Additional transformations that are used in the default configuration of the * input polynomial are applied to the result before it is returned from this * function. These transformations include: the final xor being appended to the * calculation, and the result being reflected if required. * * Calling this function multiple times is undefined. The first call to this * function returns the final result of the CRC calculation. The return * value on successive calls is undefined because the contents of the register after * accessing them is platform-specific. * * This function is not thread safe. There is only one instance of the CRC * module active at a time. Calling this function from multiple contexts may * return incorrect data or affect the current state of the module. * * \return The final CRC checksum after the reflections and final calculations * have been applied. */ uint32_t hal_crc_get_result(void); /**@}*/ #ifdef __cplusplus }; #endif #endif // DEVICE_CRC #endif // MBED_CRC_HAL_API_H /**@}*/