amiro-os / periphery-lld / periphAL.h @ 0cfdcddc
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/*
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AMiRo-OS is an operating system designed for the Autonomous Mini Robot (AMiRo) platform.
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Copyright (C) 2016..2019 Thomas Schöpping et al.
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef AMIROOS_PERIPHAL_H
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#define AMIROOS_PERIPHAL_H
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#include <amiro-lld.h> |
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/*============================================================================*/
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/* VERSION */
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/*============================================================================*/
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/**
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* @brief The periphery abstraction layer interface major version.
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* @note Changes of the major version imply incompatibilities.
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*/
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#define PERIPHAL_VERSION_MAJOR 1 |
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/**
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* @brief The periphery abstraction layer interface minor version.
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* @note A higher minor version implies new functionalty, but all old interfaces are still available.
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*/
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#define PERIPHAL_VERSION_MINOR 1 |
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/*============================================================================*/
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/* DEPENDENCIES */
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/*============================================================================*/
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#include <aosconf.h> |
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#include <hal.h> |
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/*============================================================================*/
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/* DEBUG */
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/*============================================================================*/
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#if (AMIROOS_CFG_DBG == true) || defined(__DOXYGEN__) |
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#if defined(__cplusplus)
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extern "C" { |
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#endif /* defined(__cplusplus) */ |
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void _apalDbgAssertMsg(const bool c, const char* fmt, ...); |
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void apalDbgPrintf(const char* fmt, ...); |
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#if defined(__cplusplus)
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} |
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#endif /* defined(__cplusplus) */ |
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/**
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* @brief Assert function to check a given condition.
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*
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* @param[in] c The condition to check.
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*/
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#define apalDbgAssert(c) _apalDbgAssertMsg(c, "%s(%u): apalDbgAssert failed", __FILE__, __LINE__) |
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#else /* (AMIROOS_CFG_DBG != true) */ |
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#define apalDbgAssert(constition)
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#define apalDbgAssertMsg(condition, fmt, ...)
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#define apalDbgPrintf(fmt, ...)
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#endif /* (AMIROOS_CFG_DBG == true) */ |
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/*============================================================================*/
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/* GENERAL */
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/*============================================================================*/
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/**
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* @brief Delay execution by a specific number of microseconds.
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*
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* @param[in] us Time to sleep until execution continues in microseconds.
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*/
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static inline void apalSleep(apalTime_t us) |
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{ |
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// check if the specified time can be represented by the system
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apalDbgAssert(us <= chTimeI2US(TIME_INFINITE)); |
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const sysinterval_t interval = chTimeUS2I(us);
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// TIME_IMMEDIATE makes no sense and would even cause system halt
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if (interval != TIME_IMMEDIATE) {
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chThdSleep(interval); |
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} |
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return;
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} |
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/*============================================================================*/
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/* GPIO */
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/*============================================================================*/
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#if (HAL_USE_PAL == TRUE) || defined (__DOXYGEN__)
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/**
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* @brief GPIO driver type.
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*/
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struct apalGpio_t {
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ioline_t line; |
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} PACKED_VAR; |
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/**
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* @brief Read the current value of a GPIO pin.
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*
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* @param[in] gpio GPIO to read.
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* @param[out] val Current value of the GPIO.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalGpioRead(apalGpio_t* gpio, apalGpioState_t* const val) |
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{ |
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apalDbgAssert(gpio != NULL);
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apalDbgAssert(val != NULL);
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*val = (palReadLine(gpio->line) == PAL_HIGH) ? APAL_GPIO_HIGH : APAL_GPIO_LOW; |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Set the value of a GPIO pin.
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*
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* @param[in] gpio GPIO to write.
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* @param[in] val Value to set for the GPIO.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalGpioWrite(apalGpio_t* gpio, const apalGpioState_t val) |
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{ |
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apalDbgAssert(gpio != NULL);
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// palWriteLine() is not guaranteed to be atomic, thus the scheduler is locked.
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syssts_t sysstatus = chSysGetStatusAndLockX(); |
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palWriteLine(gpio->line, (val == APAL_GPIO_HIGH) ? PAL_HIGH : PAL_LOW); |
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chSysRestoreStatusX(sysstatus); |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Toggle the output of a GPIO.
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*
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* @param[in] gpio GPIO to toggle.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalGpioToggle(apalGpio_t* gpio) |
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{ |
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apalDbgAssert(gpio != NULL);
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// palWriteLine() is not guaranteed to be atomic, thus the scheduler is locked.
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syssts_t sysstatus = chSysGetStatusAndLockX(); |
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palWriteLine(gpio->line, (palReadLine(gpio->line) == PAL_HIGH) ? PAL_LOW : PAL_HIGH); |
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chSysRestoreStatusX(sysstatus); |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Return the interrupt enable status of the GPIO.
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*
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* @param[in] gpio GPIO to check.
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* @param[out] enabled Flag, indicating whether interrupt is enabled for the GPIO.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalGpioIsInterruptEnabled(apalGpio_t* gpio, bool* const enabled) |
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{ |
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apalDbgAssert(gpio != NULL);
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apalDbgAssert(enabled != NULL);
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*enabled = palIsLineEventEnabledX(gpio->line); |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Get the current on/off state of a control GPIO.
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*
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* @param[in] gpio Control GPIO to read.
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* @param[out] val Current activation status of the control GPIO.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalControlGpioGet(const apalControlGpio_t* const cgpio, apalControlGpioState_t* const val) |
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{ |
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apalDbgAssert(cgpio != NULL);
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apalDbgAssert(cgpio->gpio != NULL);
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apalDbgAssert(val != NULL);
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*val = ((palReadLine(cgpio->gpio->line) == PAL_HIGH) ^ (cgpio->meta.active == APAL_GPIO_ACTIVE_HIGH)) ? APAL_GPIO_OFF : APAL_GPIO_ON; |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Turn a control GPIO 'on' or 'off' respectively.
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*
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* @param[in] gpio Control GPIO to set.
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* @param[in] val Activation value to set for the control GPIO.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalControlGpioSet(const apalControlGpio_t* const cgpio, const apalControlGpioState_t val) |
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{ |
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apalDbgAssert(cgpio != NULL);
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apalDbgAssert(cgpio->gpio != NULL);
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apalDbgAssert(cgpio->meta.direction == APAL_GPIO_DIRECTION_OUTPUT || cgpio->meta.direction == APAL_GPIO_DIRECTION_BIDIRECTIONAL); |
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// palWriteLine() is not guaranteed to be atomic, thus the scheduler is locked.
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syssts_t sysstatus = chSysGetStatusAndLockX(); |
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palWriteLine(cgpio->gpio->line, ((cgpio->meta.active == APAL_GPIO_ACTIVE_HIGH) ^ (val == APAL_GPIO_ON)) ? PAL_LOW : PAL_HIGH); |
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chSysRestoreStatusX(sysstatus); |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Converts an apalGpioEdge_t to an ChibiOS PAL edge.
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*/
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#define APAL2CH_EDGE(edge) \
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((edge == APAL_GPIO_EDGE_RISING) ? PAL_EVENT_MODE_RISING_EDGE : \ |
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(edge == APAL_GPIO_EDGE_FALLING) ? PAL_EVENT_MODE_FALLING_EDGE : \ |
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(edge == APAL_GPIO_EDGE_BOTH) ? PAL_EVENT_MODE_BOTH_EDGES : \ |
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PAL_EVENT_MODE_DISABLED) |
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/**
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* @brief Enable or disable the interrupt event functionality.
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*
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* @param[in] cgpio Control GPIO to set.
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* @param[in] enable Flag, indicating whether the interrupt shall be activated (true) or deactivated (false).
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalControlGpioSetInterrupt(const apalControlGpio_t* const cgpio, const bool enable) |
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{ |
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apalDbgAssert(cgpio != NULL);
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apalDbgAssert(cgpio->gpio != NULL);
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if (enable) {
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apalDbgAssert(pal_lld_get_line_event(cgpio->gpio->line) != NULL);
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palEnableLineEvent(cgpio->gpio->line, APAL2CH_EDGE(cgpio->meta.edge)); |
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} else {
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palDisableLineEvent(cgpio->gpio->line); |
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} |
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return APAL_STATUS_OK;
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} |
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#endif /* (HAL_USE_PAL == TRUE) */ |
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/*============================================================================*/
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/* PWM */
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/*============================================================================*/
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#if (HAL_USE_PWM == TRUE) || defined (__DOXYGEN__)
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/**
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* @brief PWM driver type.
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*/
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typedef PWMDriver apalPWMDriver_t;
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/**
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* @brief Set the PWM with given parameters.
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*
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* @param[in] pwm PWM driver to set.
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* @param[in] channel Channel of the PWM driver to set.
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* @param[in] width Width to set the channel to.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalPWMSet(apalPWMDriver_t* pwm, const apalPWMchannel_t channel, const apalPWMwidth_t width) |
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{ |
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apalDbgAssert(pwm != NULL);
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pwmEnableChannel(pwm, (pwmchannel_t)channel, pwm->period * ((float)width / (float)APAL_PWM_WIDTH_MAX) + 0.5f); |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Retrieve the current frequency of the PWM.
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*
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* @param[in] pwm PWM driver to read.
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* @param[out] frequency The currently set frequency.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalPWMGetFrequency(apalPWMDriver_t* pwm, apalPWMfrequency_t* const frequency) |
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{ |
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apalDbgAssert(pwm != NULL);
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apalDbgAssert(frequency != NULL);
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*frequency = pwm->config->frequency; |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Retrieve the current period of the PWM.
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*
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* @param[in] pwm PWM driver to read.
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* @param[out] period The currently set period.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalPWMGetPeriod(apalPWMDriver_t* pwm, apalPWMperiod_t* const period) |
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{ |
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apalDbgAssert(pwm != NULL);
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apalDbgAssert(period != NULL);
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*period = pwm->period; |
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return APAL_STATUS_OK;
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} |
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#endif /* (HAL_USE_PWM == TRUE) */ |
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/*============================================================================*/
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/* QEI */
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/*============================================================================*/
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#if (HAL_USE_QEI == TRUE) || defined (__DOXYGEN__)
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/**
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* @brief QEI driver type.
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*/
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typedef QEIDriver apalQEIDriver_t;
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/**
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* @brief Gets the direction of the last transition.
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*
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* @param[in] qei The QEI driver to use.
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* @param[out] direction The direction of the last transition.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalQEIGetDirection(apalQEIDriver_t* qei, apalQEIDirection_t* const direction) |
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{ |
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apalDbgAssert(qei != NULL);
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apalDbgAssert(direction != NULL);
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*direction = (qei_lld_get_direction(qei)) ? APAL_QEI_DIRECTION_DOWN : APAL_QEI_DIRECTION_UP; |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Gets the current position of the ecnoder.
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*
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* @param[in] qei The QEI driver to use.
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* @param[out] position The current position of the encoder.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalQEIGetPosition(apalQEIDriver_t* qei, apalQEICount_t* const position) |
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{ |
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apalDbgAssert(qei != NULL);
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apalDbgAssert(position != NULL);
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*position = qei_lld_get_position(qei); |
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return APAL_STATUS_OK;
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} |
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/**
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* @brief Gets the value range of the encoder.
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*
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* @param[in] qei The QEI driver to use.
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* @param[out] range The value range of the encoder.
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*
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* @return The status indicates whether the function call was successful.
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*/
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static inline apalExitStatus_t apalQEIGetRange(apalQEIDriver_t* qei, apalQEICount_t* const range) |
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{ |
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apalDbgAssert(qei != NULL);
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apalDbgAssert(range != NULL);
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*range = qei_lld_get_range(qei); |
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return APAL_STATUS_OK;
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} |
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#endif /* (HAL_USE_QEI == TRUE) */ |
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/*============================================================================*/
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/* I2C */
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/*============================================================================*/
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#if (HAL_USE_I2C == TRUE) || defined(__DOXYGEN__)
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/**
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* @brief I2C driver type.
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*/
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typedef I2CDriver apalI2CDriver_t;
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/**
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* @brief Transmit data and receive a response.
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*
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* @param[in] i2cd The I2C driver to use.
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* @param[in] addr Address to write to.
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* @param[in] txbuf Buffer containing data to send.
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* @param[in] txbytes Number of bytes to send.
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* @param[out] rxbuf Buffer to store a response to.
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* @param[in] rxbytes Number of bytes to receive.
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* @param[in] timeout Timeout for the function to return (in microseconds).
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*
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* @return The status indicates whether the function call was succesful or a timeout occurred.
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*/
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static inline apalExitStatus_t apalI2CMasterTransmit(apalI2CDriver_t* i2cd, const apalI2Caddr_t addr, const uint8_t* const txbuf, const size_t txbytes, uint8_t* const rxbuf, const size_t rxbytes, const apalTime_t timeout) |
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{ |
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apalDbgAssert(i2cd != NULL);
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#if (I2C_USE_MUTUAL_EXCLUSION == TRUE)
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// check whether the I2C driver was locked externally
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const bool i2cd_locked_external = i2cd->mutex.owner == currp; |
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if (!i2cd_locked_external) {
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i2cAcquireBus(i2cd); |
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} |
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#endif /* (I2C_USE_MUTUAL_EXCLUSION == TRUE) */ |
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#pragma GCC diagnostic push
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#pragma GCC diagnostic ignored "-Wtype-limits" |
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#if defined(STM32F1XX_I2C)
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// Due to a hardware limitation, for STM32F1 platform the minimum number of bytes that can be received is two.
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msg_t status = MSG_OK; |
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if (rxbytes == 1) { |
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uint8_t buffer[2];
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status = i2cMasterTransmitTimeout(i2cd, addr, txbuf, txbytes, buffer, 2, ((timeout >= TIME_INFINITE) ? TIME_INFINITE : TIME_US2I(timeout)) );
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rxbuf[0] = buffer[0]; |
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} else {
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status = i2cMasterTransmitTimeout(i2cd, addr, txbuf, txbytes, rxbuf, rxbytes, ((timeout >= TIME_INFINITE) ? TIME_INFINITE : TIME_US2I(timeout)) ); |
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} |
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#else /* defined(STM32F1XX_I2C) */ |
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const msg_t status = i2cMasterTransmitTimeout(i2cd, addr, txbuf, txbytes, rxbuf, rxbytes, ((timeout >= TIME_INFINITE) ? TIME_INFINITE : TIME_US2I(timeout)) );
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#endif /* defined(STM32F1XX_I2C) */ |
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#pragma GCC diagnostic pop
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#if (I2C_USE_MUTUAL_EXCLUSION == TRUE)
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if (!i2cd_locked_external) {
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i2cReleaseBus(i2cd); |
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} |
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#endif /* (I2C_USE_MUTUAL_EXCLUSION == TRUE) */ |
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switch (status)
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{ |
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case MSG_OK:
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#if defined(STM32F1XX_I2C)
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return (rxbytes != 1) ? APAL_STATUS_OK : APAL_STATUS_WARNING; |
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#else /* defined(STM32F1XX_I2C) */ |
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return APAL_STATUS_OK;
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#endif /* defined(STM32F1XX_I2C) */ |
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case MSG_TIMEOUT:
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return APAL_STATUS_TIMEOUT;
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case MSG_RESET:
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default:
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return APAL_STATUS_ERROR;
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} |
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} |
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/**
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* @brief Read data from a specific address.
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*
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* @param[in] i2cd The I2C driver to use.
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* @param[in] addr Address to read.
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* @param[out] rxbuf Buffer to store the response to.
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* @param[in] rxbytes Number of bytes to receive.
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* @param[in] timeout Timeout for the function to return (in microseconds).
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*
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472 |
* @return The status indicates whether the function call was succesful or a timeout occurred.
|
473 |
*/
|
474 |
static inline apalExitStatus_t apalI2CMasterReceive(apalI2CDriver_t* i2cd, const apalI2Caddr_t addr, uint8_t* const rxbuf, const size_t rxbytes, const apalTime_t timeout) |
475 |
{ |
476 |
apalDbgAssert(i2cd != NULL);
|
477 |
|
478 |
#if (I2C_USE_MUTUAL_EXCLUSION == TRUE)
|
479 |
// check whether the I2C driver was locked externally
|
480 |
const bool i2cd_locked_external = i2cd->mutex.owner == currp; |
481 |
if (!i2cd_locked_external) {
|
482 |
i2cAcquireBus(i2cd); |
483 |
} |
484 |
#endif /* (I2C_USE_MUTUAL_EXCLUSION == TRUE) */ |
485 |
|
486 |
#pragma GCC diagnostic push
|
487 |
#pragma GCC diagnostic ignored "-Wtype-limits" |
488 |
#if defined(STM32F1XX_I2C)
|
489 |
// Due to a hardware limitation, for STM32F1 platform the minimum number of bytes that can be received is two.
|
490 |
msg_t status = MSG_OK; |
491 |
if (rxbytes == 1) { |
492 |
uint8_t buffer[2];
|
493 |
status = i2cMasterReceiveTimeout(i2cd, addr, buffer, 2, ((timeout >= TIME_INFINITE) ? TIME_INFINITE : TIME_US2I(timeout)) );
|
494 |
rxbuf[0] = buffer[0]; |
495 |
} else {
|
496 |
status = i2cMasterReceiveTimeout(i2cd, addr, rxbuf, rxbytes, ((timeout >= TIME_INFINITE) ? TIME_INFINITE : TIME_US2I(timeout)) ); |
497 |
} |
498 |
#else /* defined(STM32F1XX_I2C) */ |
499 |
const msg_t status = i2cMasterReceiveTimeout(i2cd, addr, rxbuf, rxbytes, ((timeout >= TIME_INFINITE) ? TIME_INFINITE : TIME_US2I(timeout)) );
|
500 |
#endif /* defined(STM32F1XX_I2C) */ |
501 |
#pragma GCC diagnostic pop
|
502 |
|
503 |
#if (I2C_USE_MUTUAL_EXCLUSION == TRUE)
|
504 |
if (!i2cd_locked_external) {
|
505 |
i2cReleaseBus(i2cd); |
506 |
} |
507 |
#endif /* (I2C_USE_MUTUAL_EXCLUSION == TRUE) */ |
508 |
|
509 |
switch (status)
|
510 |
{ |
511 |
case MSG_OK:
|
512 |
#if defined(STM32F1XX_I2C)
|
513 |
return (rxbytes != 1) ? APAL_STATUS_OK : APAL_STATUS_WARNING; |
514 |
#else /* defined(STM32F1XX_I2C) */ |
515 |
return APAL_STATUS_OK;
|
516 |
#endif /* defined(STM32F1XX_I2C) */ |
517 |
case MSG_TIMEOUT:
|
518 |
return APAL_STATUS_TIMEOUT;
|
519 |
case MSG_RESET:
|
520 |
default:
|
521 |
return APAL_STATUS_ERROR;
|
522 |
} |
523 |
} |
524 |
|
525 |
#endif /* (HAL_USE_I2C == TRUE) */ |
526 |
|
527 |
/*============================================================================*/
|
528 |
/* SPI */
|
529 |
/*============================================================================*/
|
530 |
|
531 |
#if (HAL_USE_SPI == TRUE) || defined(__DOXYGEN__)
|
532 |
|
533 |
/**
|
534 |
* @brief SPI driver type.
|
535 |
*/
|
536 |
typedef SPIDriver apalSPIDriver_t;
|
537 |
|
538 |
/**
|
539 |
* @brief SPI confguration type.
|
540 |
*/
|
541 |
typedef SPIConfig apalSPIConfig_t;
|
542 |
|
543 |
/**
|
544 |
* @brief Reconfigure an SPI driver.
|
545 |
*
|
546 |
* @param[in] spid The SPI driver to be reconfigured.
|
547 |
* @param[in] config Configuration to apply.
|
548 |
*
|
549 |
* @return The status indicates whether the function call was succesful.
|
550 |
*/
|
551 |
static inline apalExitStatus_t apalSPIReconfigure(apalSPIDriver_t* spid, const apalSPIConfig_t* config) |
552 |
{ |
553 |
apalDbgAssert(spid != NULL);
|
554 |
apalDbgAssert(config != NULL);
|
555 |
|
556 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
557 |
// check whether the SPI driver was locked externally
|
558 |
const bool spid_locked_external = spid->mutex.owner == currp; |
559 |
if (!spid_locked_external) {
|
560 |
spiAcquireBus(spid); |
561 |
} |
562 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
563 |
|
564 |
spiStop(spid); |
565 |
spiStart(spid, config); |
566 |
|
567 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
568 |
if (!spid_locked_external) {
|
569 |
spiReleaseBus(spid); |
570 |
} |
571 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
572 |
|
573 |
return APAL_STATUS_OK;
|
574 |
} |
575 |
|
576 |
/**
|
577 |
* @brief Transmit and receive data from SPI
|
578 |
*
|
579 |
* @param[in] spid The SPI driver to use.
|
580 |
* @param[in] txData Buffer containing data to send.
|
581 |
* @param[out] rxData Buffer to store.
|
582 |
* @param[in] length Number of bytes to send.
|
583 |
*
|
584 |
* @return The status indicates whether the function call was succesful.
|
585 |
*/
|
586 |
static inline apalExitStatus_t apalSPIExchange(apalSPIDriver_t* spid, const uint8_t* const txData , uint8_t* const rxData, const size_t length) |
587 |
{ |
588 |
apalDbgAssert(spid != NULL);
|
589 |
|
590 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
591 |
// check whether the SPI driver was locked externally
|
592 |
const bool spid_locked_external = spid->mutex.owner == currp; |
593 |
if (!spid_locked_external) {
|
594 |
spiAcquireBus(spid); |
595 |
} |
596 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
597 |
|
598 |
spiSelect(spid); |
599 |
spiExchange(spid, length, txData, rxData); |
600 |
spiUnselect(spid); |
601 |
|
602 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
603 |
if (!spid_locked_external) {
|
604 |
spiReleaseBus(spid); |
605 |
} |
606 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
607 |
|
608 |
return APAL_STATUS_OK;
|
609 |
} |
610 |
|
611 |
/**
|
612 |
* @brief Receive data from SPI
|
613 |
*
|
614 |
* @param[in] spid The SPI driver to use.
|
615 |
* @param[out] data Buffer to store.
|
616 |
* @param[in] length Number of bytes to send.
|
617 |
*
|
618 |
* @return The status indicates whether the function call was succesful.
|
619 |
*/
|
620 |
static inline apalExitStatus_t apalSPIReceive(apalSPIDriver_t* spid, uint8_t* const data, const size_t length) |
621 |
{ |
622 |
apalDbgAssert(spid != NULL);
|
623 |
|
624 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
625 |
// check whether the SPI driver was locked externally
|
626 |
const bool spid_locked_external = spid->mutex.owner == currp; |
627 |
if (!spid_locked_external) {
|
628 |
spiAcquireBus(spid); |
629 |
} |
630 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
631 |
|
632 |
spiSelect(spid); |
633 |
spiReceive(spid, length, data); |
634 |
spiUnselect(spid); |
635 |
|
636 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
637 |
if (!spid_locked_external) {
|
638 |
spiReleaseBus(spid); |
639 |
} |
640 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
641 |
|
642 |
return APAL_STATUS_OK;
|
643 |
} |
644 |
|
645 |
/**
|
646 |
* @brief Transmit data to SPI
|
647 |
*
|
648 |
* @param[in] spid The SPI driver to use.
|
649 |
* @param[in] data Buffer containing data to send.
|
650 |
* @param[in] length Number of bytes to send.
|
651 |
*
|
652 |
* @return The status indicates whether the function call was succesful.
|
653 |
*/
|
654 |
static inline apalExitStatus_t apalSPITransmit(apalSPIDriver_t* spid, const uint8_t* const data, const size_t length) |
655 |
{ |
656 |
apalDbgAssert(spid != NULL);
|
657 |
|
658 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
659 |
// check whether the SPI driver was locked externally
|
660 |
const bool spid_locked_external = spid->mutex.owner == currp; |
661 |
if (!spid_locked_external) {
|
662 |
spiAcquireBus(spid); |
663 |
} |
664 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
665 |
|
666 |
spiSelect(spid); |
667 |
spiSend(spid, length, data); |
668 |
spiUnselect(spid); |
669 |
|
670 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
671 |
if (!spid_locked_external) {
|
672 |
spiReleaseBus(spid); |
673 |
} |
674 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
675 |
|
676 |
return APAL_STATUS_OK;
|
677 |
} |
678 |
|
679 |
/**
|
680 |
* @brief Transmit data to SPI and receive data afterwards without releasing the bus in between.
|
681 |
*
|
682 |
* @param spid The SPI driver to use.
|
683 |
* @param txData Transmit data buffer.
|
684 |
* @param rxData Receive data buffer.
|
685 |
* @param txLength Number of bytes to send.
|
686 |
* @param rxLength Number of bytes to receive.
|
687 |
*
|
688 |
* @return The status indicates whether the function call was succesful.
|
689 |
*/
|
690 |
static inline apalExitStatus_t apalSPITransmitAndReceive(apalSPIDriver_t* spid, const uint8_t* const txData , uint8_t* const rxData, const size_t txLength, const size_t rxLength) |
691 |
{ |
692 |
apalDbgAssert(spid != NULL);
|
693 |
|
694 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
695 |
// check whether the SPI driver was locked externally
|
696 |
const bool spid_locked_external = spid->mutex.owner == currp; |
697 |
if (!spid_locked_external) {
|
698 |
spiAcquireBus(spid); |
699 |
} |
700 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
701 |
|
702 |
spiSelect(spid); |
703 |
spiSend(spid, txLength, txData); |
704 |
spiReceive(spid, rxLength, rxData); |
705 |
spiUnselect(spid); |
706 |
|
707 |
#if (SPI_USE_MUTUAL_EXCLUSION == TRUE)
|
708 |
if (!spid_locked_external) {
|
709 |
spiReleaseBus(spid); |
710 |
} |
711 |
#endif /* (SPI_USE_MUTUAL_EXCLUSION == TRUE) */ |
712 |
|
713 |
return APAL_STATUS_OK;
|
714 |
} |
715 |
|
716 |
#endif /* (HAL_USE_SPI == TRUE) */ |
717 |
|
718 |
#endif /* AMIROOS_PERIPHAL_H */ |