1 /*
2  * Copyright (c) 2016, Freescale Semiconductor, Inc.
3  * Copyright 2016-2023 NXP
4  * All rights reserved.
5  *
6  * SPDX-License-Identifier: BSD-3-Clause
7  */
8 #ifndef FSL_USART_H_
9 #define FSL_USART_H_
10 
11 #include "fsl_common.h"
12 
13 /*!
14  * @addtogroup usart_driver
15  * @{
16  */
17 
18 /*******************************************************************************
19  * Definitions
20  ******************************************************************************/
21 
22 /*! @name Driver version */
23 /*! @{ */
24 /*! @brief USART driver version. */
25 #define FSL_USART_DRIVER_VERSION (MAKE_VERSION(2, 8, 3))
26 /*! @} */
27 
28 #define USART_FIFOTRIG_TXLVL_GET(base) (((base)->FIFOTRIG & USART_FIFOTRIG_TXLVL_MASK) >> USART_FIFOTRIG_TXLVL_SHIFT)
29 #define USART_FIFOTRIG_RXLVL_GET(base) (((base)->FIFOTRIG & USART_FIFOTRIG_RXLVL_MASK) >> USART_FIFOTRIG_RXLVL_SHIFT)
30 
31 /*! @brief Retry times for waiting flag.
32  *
33  * Defining to zero means to keep waiting for the flag until it is assert/deassert in blocking transfer,
34  * otherwise the program will wait until the UART_RETRY_TIMES counts down to 0,
35  * if the flag still remains unchanged then program will return kStatus_USART_Timeout.
36  * It is not advised to use this macro in formal application to prevent any hardware error
37  * because the actual wait period is affected by the compiler and optimization.
38  */
39 #ifndef UART_RETRY_TIMES
40 #define UART_RETRY_TIMES 0U
41 #endif
42 
43 /*! @brief Error codes for the USART driver. */
44 enum
45 {
46     kStatus_USART_TxBusy              = MAKE_STATUS(kStatusGroup_LPC_USART, 0),  /*!< Transmitter is busy. */
47     kStatus_USART_RxBusy              = MAKE_STATUS(kStatusGroup_LPC_USART, 1),  /*!< Receiver is busy. */
48     kStatus_USART_TxIdle              = MAKE_STATUS(kStatusGroup_LPC_USART, 2),  /*!< USART transmitter is idle. */
49     kStatus_USART_RxIdle              = MAKE_STATUS(kStatusGroup_LPC_USART, 3),  /*!< USART receiver is idle. */
50     kStatus_USART_TxError             = MAKE_STATUS(kStatusGroup_LPC_USART, 7),  /*!< Error happens on txFIFO. */
51     kStatus_USART_RxError             = MAKE_STATUS(kStatusGroup_LPC_USART, 9),  /*!< Error happens on rxFIFO. */
52     kStatus_USART_RxRingBufferOverrun = MAKE_STATUS(kStatusGroup_LPC_USART, 8),  /*!< Error happens on rx ring buffer */
53     kStatus_USART_NoiseError          = MAKE_STATUS(kStatusGroup_LPC_USART, 10), /*!< USART noise error. */
54     kStatus_USART_FramingError        = MAKE_STATUS(kStatusGroup_LPC_USART, 11), /*!< USART framing error. */
55     kStatus_USART_ParityError         = MAKE_STATUS(kStatusGroup_LPC_USART, 12), /*!< USART parity error. */
56     kStatus_USART_BaudrateNotSupport =
57         MAKE_STATUS(kStatusGroup_LPC_USART, 13), /*!< Baudrate is not support in current clock source */
58 #if UART_RETRY_TIMES
59     kStatus_USART_Timeout = MAKE_STATUS(kStatusGroup_LPC_USART, 14), /*!< USART time out. */
60 #endif
61 };
62 
63 /*! @brief USART synchronous mode. */
64 typedef enum _usart_sync_mode
65 {
66     kUSART_SyncModeDisabled = 0x0U, /*!< Asynchronous mode.       */
67     kUSART_SyncModeSlave    = 0x2U, /*!< Synchronous slave mode.  */
68     kUSART_SyncModeMaster   = 0x3U, /*!< Synchronous master mode. */
69 } usart_sync_mode_t;
70 
71 /*! @brief USART parity mode. */
72 typedef enum _usart_parity_mode
73 {
74     kUSART_ParityDisabled = 0x0U, /*!< Parity disabled */
75     kUSART_ParityEven     = 0x2U, /*!< Parity enabled, type even, bit setting: PE|PT = 10 */
76     kUSART_ParityOdd      = 0x3U, /*!< Parity enabled, type odd,  bit setting: PE|PT = 11 */
77 } usart_parity_mode_t;
78 
79 /*! @brief USART stop bit count. */
80 typedef enum _usart_stop_bit_count
81 {
82     kUSART_OneStopBit = 0U, /*!< One stop bit */
83     kUSART_TwoStopBit = 1U, /*!< Two stop bits */
84 } usart_stop_bit_count_t;
85 
86 /*! @brief USART data size. */
87 typedef enum _usart_data_len
88 {
89     kUSART_7BitsPerChar = 0U, /*!< Seven bit mode */
90     kUSART_8BitsPerChar = 1U, /*!< Eight bit mode */
91 } usart_data_len_t;
92 
93 /*! @brief USART clock polarity configuration, used in sync mode.*/
94 typedef enum _usart_clock_polarity
95 {
96     kUSART_RxSampleOnFallingEdge = 0x0U, /*!< Un_RXD is sampled on the falling edge of SCLK. */
97     kUSART_RxSampleOnRisingEdge  = 0x1U, /*!< Un_RXD is sampled on the rising edge of SCLK. */
98 } usart_clock_polarity_t;
99 
100 /*! @brief txFIFO watermark values */
101 typedef enum _usart_txfifo_watermark
102 {
103     kUSART_TxFifo0 = 0, /*!< USART tx watermark is empty */
104     kUSART_TxFifo1 = 1, /*!< USART tx watermark at 1 item */
105     kUSART_TxFifo2 = 2, /*!< USART tx watermark at 2 items */
106     kUSART_TxFifo3 = 3, /*!< USART tx watermark at 3 items */
107     kUSART_TxFifo4 = 4, /*!< USART tx watermark at 4 items */
108     kUSART_TxFifo5 = 5, /*!< USART tx watermark at 5 items */
109     kUSART_TxFifo6 = 6, /*!< USART tx watermark at 6 items */
110     kUSART_TxFifo7 = 7, /*!< USART tx watermark at 7 items */
111 } usart_txfifo_watermark_t;
112 
113 /*! @brief rxFIFO watermark values */
114 typedef enum _usart_rxfifo_watermark
115 {
116     kUSART_RxFifo1 = 0, /*!< USART rx watermark at 1 item */
117     kUSART_RxFifo2 = 1, /*!< USART rx watermark at 2 items */
118     kUSART_RxFifo3 = 2, /*!< USART rx watermark at 3 items */
119     kUSART_RxFifo4 = 3, /*!< USART rx watermark at 4 items */
120     kUSART_RxFifo5 = 4, /*!< USART rx watermark at 5 items */
121     kUSART_RxFifo6 = 5, /*!< USART rx watermark at 6 items */
122     kUSART_RxFifo7 = 6, /*!< USART rx watermark at 7 items */
123     kUSART_RxFifo8 = 7, /*!< USART rx watermark at 8 items */
124 } usart_rxfifo_watermark_t;
125 
126 /*!
127  * @brief USART interrupt configuration structure, default settings all disabled.
128  */
129 enum _usart_interrupt_enable
130 {
131     kUSART_TxErrorInterruptEnable = (USART_FIFOINTENSET_TXERR_MASK),
132     kUSART_RxErrorInterruptEnable = (USART_FIFOINTENSET_RXERR_MASK),
133     kUSART_TxLevelInterruptEnable = (USART_FIFOINTENSET_TXLVL_MASK),
134     kUSART_RxLevelInterruptEnable = (USART_FIFOINTENSET_RXLVL_MASK),
135     kUSART_TxIdleInterruptEnable  = (USART_INTENSET_TXIDLEEN_MASK << 16U), /*!< Transmitter idle. */
136     kUSART_CtsChangeInterruptEnable =
137         (USART_INTENSET_DELTACTSEN_MASK << 16U), /*!< Change in the state of the CTS input. */
138     kUSART_RxBreakChangeInterruptEnable =
139         (USART_INTENSET_DELTARXBRKEN_MASK),                              /*!< Break condition asserted or deasserted. */
140     kUSART_RxStartInterruptEnable       = (USART_INTENSET_STARTEN_MASK), /*!< Rx start bit detected. */
141     kUSART_FramingErrorInterruptEnable  = (USART_INTENSET_FRAMERREN_MASK),   /*!< Framing error detected. */
142     kUSART_ParityErrorInterruptEnable   = (USART_INTENSET_PARITYERREN_MASK), /*!< Parity error detected. */
143     kUSART_NoiseErrorInterruptEnable    = (USART_INTENSET_RXNOISEEN_MASK),   /*!< Noise error detected. */
144     kUSART_AutoBaudErrorInterruptEnable = (USART_INTENSET_ABERREN_MASK),     /*!< Auto baudrate error detected. */
145 #if defined(FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG) && FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG
146     kUSART_RxTimeoutInterruptEnable = (USART_FIFOINTENSET_RXTIMEOUT_MASK), /*!< Receive timeout detected. */
147 #endif
148     kUSART_AllInterruptEnables =
149         kUSART_TxErrorInterruptEnable | kUSART_RxErrorInterruptEnable | kUSART_TxLevelInterruptEnable |
150         kUSART_RxLevelInterruptEnable | kUSART_TxIdleInterruptEnable | kUSART_CtsChangeInterruptEnable |
151         kUSART_RxBreakChangeInterruptEnable | kUSART_RxStartInterruptEnable | kUSART_FramingErrorInterruptEnable |
152         kUSART_ParityErrorInterruptEnable | kUSART_NoiseErrorInterruptEnable |
153 #if defined(FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG) && FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG
154         kUSART_RxTimeoutInterruptEnable |
155 #endif
156         kUSART_AutoBaudErrorInterruptEnable,
157 };
158 
159 /*!
160  * @brief USART status flags.
161  *
162  * This provides constants for the USART status flags for use in the USART functions.
163  */
164 enum _usart_flags
165 {
166     kUSART_TxError            = (USART_FIFOSTAT_TXERR_MASK),       /*!< TEERR bit, sets if TX buffer is error */
167     kUSART_RxError            = (USART_FIFOSTAT_RXERR_MASK),       /*!< RXERR bit, sets if RX buffer is error */
168     kUSART_TxFifoEmptyFlag    = (USART_FIFOSTAT_TXEMPTY_MASK),     /*!< TXEMPTY bit, sets if TX buffer is empty */
169     kUSART_TxFifoNotFullFlag  = (USART_FIFOSTAT_TXNOTFULL_MASK),   /*!< TXNOTFULL bit, sets if TX buffer is not full */
170     kUSART_RxFifoNotEmptyFlag = (USART_FIFOSTAT_RXNOTEMPTY_MASK),  /*!< RXNOEMPTY bit, sets if RX buffer is not empty */
171     kUSART_RxFifoFullFlag     = (USART_FIFOSTAT_RXFULL_MASK),      /*!< RXFULL bit, sets if RX buffer is full */
172     kUSART_RxIdleFlag         = (USART_STAT_RXIDLE_MASK << 16U),   /*!< Receiver idle. */
173     kUSART_TxIdleFlag         = (USART_STAT_TXIDLE_MASK << 16U),   /*!< Transmitter idle. */
174     kUSART_CtsAssertFlag      = (USART_STAT_CTS_MASK << 16U),      /*!< CTS signal high. */
175     kUSART_CtsChangeFlag      = (USART_STAT_DELTACTS_MASK << 16U), /*!< CTS signal changed interrupt status. */
176     kUSART_BreakDetectFlag = (USART_STAT_RXBRK_MASK), /*!< Break detected. Self cleared when rx pin goes high again. */
177     kUSART_BreakDetectChangeFlag = (USART_STAT_DELTARXBRK_MASK), /*!< Break detect change interrupt flag. A change in
178                                                                     the state of receiver break detection. */
179     kUSART_RxStartFlag       = (USART_STAT_START_MASK),          /*!< Rx start bit detected interrupt flag. */
180     kUSART_FramingErrorFlag  = (USART_STAT_FRAMERRINT_MASK),     /*!< Framing error interrupt flag. */
181     kUSART_ParityErrorFlag   = (USART_STAT_PARITYERRINT_MASK),   /*!< parity error interrupt flag. */
182     kUSART_NoiseErrorFlag    = (USART_STAT_RXNOISEINT_MASK),     /*!< Noise error interrupt flag. */
183     kUSART_AutobaudErrorFlag = (USART_STAT_ABERR_MASK), /*!< Auto baudrate error interrupt flag, caused by the baudrate
184                                                            counter timeout before the end of start bit. */
185 #if defined(FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG) && FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG
186     kUSART_RxTimeoutFlag = (USART_FIFOSTAT_RXTIMEOUT_MASK), /*!< RXTIMEOUT bit, sets if RX FIFO Timeout. */
187 #endif
188     kUSART_AllClearFlags = kUSART_TxError | kUSART_RxError | kUSART_CtsChangeFlag | kUSART_BreakDetectChangeFlag |
189                            kUSART_RxStartFlag | kUSART_FramingErrorFlag | kUSART_ParityErrorFlag |
190 #if defined(FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG) && FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG
191                            kUSART_RxTimeoutFlag |
192 #endif
193                            kUSART_NoiseErrorFlag | kUSART_AutobaudErrorFlag,
194 };
195 
196 #if defined(FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG) && FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG
197 /*! @brief USART receive timeout configuration structure. */
198 typedef struct _usart_rx_timeout_config
199 {
200     bool enable;                /*!< Enable RX timeout */
201     bool resetCounterOnEmpty;   /*!< Enable RX timeout counter reset when RX FIFO becames empty. */
202     bool resetCounterOnReceive; /*!< Enable RX timeout counter reset when RX FIFO receives data from the transmitter
203                                    side. */
204     uint32_t counter;           /*!< RX timeout counter*/
205     uint8_t prescaler;          /*!< RX timeout prescaler*/
206 } usart_rx_timeout_config;
207 #endif
208 
209 /*! @brief USART configuration structure. */
210 typedef struct _usart_config
211 {
212     uint32_t baudRate_Bps;                /*!< USART baud rate  */
213     usart_parity_mode_t parityMode;       /*!< Parity mode, disabled (default), even, odd */
214     usart_stop_bit_count_t stopBitCount;  /*!< Number of stop bits, 1 stop bit (default) or 2 stop bits  */
215     usart_data_len_t bitCountPerChar;     /*!< Data length - 7 bit, 8 bit  */
216     bool loopback;                        /*!< Enable peripheral loopback */
217     bool enableRx;                        /*!< Enable RX */
218     bool enableTx;                        /*!< Enable TX */
219     bool enableContinuousSCLK;            /*!< USART continuous Clock generation enable in synchronous master mode. */
220     bool enableMode32k;                   /*!< USART uses 32 kHz clock from the RTC oscillator as the clock source. */
221     bool enableHardwareFlowControl;       /*!< Enable hardware control RTS/CTS */
222     usart_txfifo_watermark_t txWatermark; /*!< txFIFO watermark */
223     usart_rxfifo_watermark_t rxWatermark; /*!< rxFIFO watermark */
224     usart_sync_mode_t syncMode; /*!< Transfer mode select - asynchronous, synchronous master, synchronous slave. */
225     usart_clock_polarity_t clockPolarity; /*!< Selects the clock polarity and sampling edge in synchronous mode. */
226 #if defined(FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG) && FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG
227     usart_rx_timeout_config rxTimeout; /*!< rx timeout configuration */
228 #endif
229 } usart_config_t;
230 
231 /*! @brief USART transfer structure. */
232 typedef struct _usart_transfer
233 {
234     /*
235      * Use separate TX and RX data pointer, because TX data is const data.
236      * The member data is kept for backward compatibility.
237      */
238     union
239     {
240         uint8_t *data;         /*!< The buffer of data to be transfer.*/
241         uint8_t *rxData;       /*!< The buffer to receive data. */
242         const uint8_t *txData; /*!< The buffer of data to be sent. */
243     };
244     size_t dataSize; /*!< The byte count to be transfer. */
245 } usart_transfer_t;
246 
247 /* Forward declaration of the handle typedef. */
248 typedef struct _usart_handle usart_handle_t;
249 
250 /*! @brief USART transfer callback function. */
251 typedef void (*usart_transfer_callback_t)(USART_Type *base, usart_handle_t *handle, status_t status, void *userData);
252 
253 /*! @brief USART handle structure. */
254 struct _usart_handle
255 {
256     const uint8_t *volatile txData; /*!< Address of remaining data to send. */
257     volatile size_t txDataSize;     /*!< Size of the remaining data to send. */
258     size_t txDataSizeAll;           /*!< Size of the data to send out. */
259     uint8_t *volatile rxData;       /*!< Address of remaining data to receive. */
260     volatile size_t rxDataSize;     /*!< Size of the remaining data to receive. */
261     size_t rxDataSizeAll;           /*!< Size of the data to receive. */
262 
263     uint8_t *rxRingBuffer;              /*!< Start address of the receiver ring buffer. */
264     size_t rxRingBufferSize;            /*!< Size of the ring buffer. */
265     volatile uint16_t rxRingBufferHead; /*!< Index for the driver to store received data into ring buffer. */
266     volatile uint16_t rxRingBufferTail; /*!< Index for the user to get data from the ring buffer. */
267 
268     usart_transfer_callback_t callback; /*!< Callback function. */
269     void *userData;                     /*!< USART callback function parameter.*/
270 
271     volatile uint8_t txState; /*!< TX transfer state. */
272     volatile uint8_t rxState; /*!< RX transfer state */
273 
274     uint8_t txWatermark; /*!< txFIFO watermark */
275     uint8_t rxWatermark; /*!< rxFIFO watermark */
276 };
277 
278 /*! @brief Typedef for usart interrupt handler. */
279 typedef void (*flexcomm_usart_irq_handler_t)(USART_Type *base, usart_handle_t *handle);
280 
281 /*******************************************************************************
282  * API
283  ******************************************************************************/
284 
285 #if defined(__cplusplus)
286 extern "C" {
287 #endif /* _cplusplus */
288 
289 /*! @brief Returns instance number for USART peripheral base address. */
290 uint32_t USART_GetInstance(USART_Type *base);
291 
292 /*!
293  * @name Initialization and deinitialization
294  * @{
295  */
296 
297 /*!
298  * @brief Initializes a USART instance with user configuration structure and peripheral clock.
299  *
300  * This function configures the USART module with the user-defined settings. The user can configure the configuration
301  * structure and also get the default configuration by using the USART_GetDefaultConfig() function.
302  * Example below shows how to use this API to configure USART.
303  * @code
304  *  usart_config_t usartConfig;
305  *  usartConfig.baudRate_Bps = 115200U;
306  *  usartConfig.parityMode = kUSART_ParityDisabled;
307  *  usartConfig.stopBitCount = kUSART_OneStopBit;
308  *  USART_Init(USART1, &usartConfig, 20000000U);
309  * @endcode
310  *
311  * @param base USART peripheral base address.
312  * @param config Pointer to user-defined configuration structure.
313  * @param srcClock_Hz USART clock source frequency in HZ.
314  * @retval kStatus_USART_BaudrateNotSupport Baudrate is not support in current clock source.
315  * @retval kStatus_InvalidArgument USART base address is not valid
316  * @retval kStatus_Success Status USART initialize succeed
317  */
318 status_t USART_Init(USART_Type *base, const usart_config_t *config, uint32_t srcClock_Hz);
319 #if defined(FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG) && FSL_FEATURE_USART_HAS_FIFORXTIMEOUTCFG
320 /*!
321  * @brief Calculate the USART instance RX timeout prescaler and counter.
322  *
323  * This function for calculate the USART RXFIFO timeout config. This function is used to calculate
324  * suitable prescaler and counter for target_us.
325  * @code
326  *   usart_config_t config;
327  *   config.rxWatermark                     = kUSART_RxFifo2;
328  *   config.rxTimeout.enable                = true;
329  *   config.rxTimeout.resetCounterOnEmpty   = true;
330  *   config.rxTimeout.resetCounterOnReceive = true;
331  *   USART_CalcTimeoutConfig(200U, &config.rxTimeout.prescaler, &config.rxTimeout.counter,
332  *                                    CLOCK_GetFreq(kCLOCK_BusClk));
333  * @endcode
334  * @param target_us  Time for rx timeout unit us.
335  * @param rxTimeoutPrescaler The prescaler to be setted after function.
336  * @param rxTimeoutcounter The counter to be setted after function.
337  * @param srcClock_Hz The clockSrc for rx timeout.
338  */
339 void USART_CalcTimeoutConfig(uint32_t target_us,
340                              uint8_t *rxTimeoutPrescaler,
341                              uint32_t *rxTimeoutcounter,
342                              uint32_t srcClock_Hz);
343 /*!
344  * @brief Sets the USART instance RX timeout config.
345  *
346  * This function configures the USART RXFIFO timeout config. This function is used to config
347  * the USART RXFIFO timeout config after the USART module is initialized by the USART_Init.
348  *
349  * @param base USART peripheral base address.
350  * @param config pointer to receive timeout configuration structure.
351  */
352 void USART_SetRxTimeoutConfig(USART_Type *base, const usart_rx_timeout_config *config);
353 #endif
354 /*!
355  * @brief Deinitializes a USART instance.
356  *
357  * This function waits for TX complete, disables TX and RX, and disables the USART clock.
358  *
359  * @param base USART peripheral base address.
360  */
361 void USART_Deinit(USART_Type *base);
362 
363 /*!
364  * @brief Gets the default configuration structure.
365  *
366  * This function initializes the USART configuration structure to a default value. The default
367  * values are:
368  *   usartConfig->baudRate_Bps = 115200U;
369  *   usartConfig->parityMode = kUSART_ParityDisabled;
370  *   usartConfig->stopBitCount = kUSART_OneStopBit;
371  *   usartConfig->bitCountPerChar = kUSART_8BitsPerChar;
372  *   usartConfig->loopback = false;
373  *   usartConfig->enableTx = false;
374  *   usartConfig->enableRx = false;
375  *
376  * @param config Pointer to configuration structure.
377  */
378 void USART_GetDefaultConfig(usart_config_t *config);
379 
380 /*!
381  * @brief Sets the USART instance baud rate.
382  *
383  * This function configures the USART module baud rate. This function is used to update
384  * the USART module baud rate after the USART module is initialized by the USART_Init.
385  * @code
386  *  USART_SetBaudRate(USART1, 115200U, 20000000U);
387  * @endcode
388  *
389  * @param base USART peripheral base address.
390  * @param baudrate_Bps USART baudrate to be set.
391  * @param srcClock_Hz USART clock source frequency in HZ.
392  * @retval kStatus_USART_BaudrateNotSupport Baudrate is not support in current clock source.
393  * @retval kStatus_Success Set baudrate succeed.
394  * @retval kStatus_InvalidArgument One or more arguments are invalid.
395  */
396 status_t USART_SetBaudRate(USART_Type *base, uint32_t baudrate_Bps, uint32_t srcClock_Hz);
397 
398 /*!
399  * @brief Enable 32 kHz mode which USART uses clock from the RTC oscillator as the clock source
400  *
401  * Please note that in order to use a 32 kHz clock to operate USART properly, the RTC oscillator
402  * and its 32 kHz output must be manully enabled by user, by calling RTC_Init and setting
403  * SYSCON_RTCOSCCTRL_EN bit to 1.
404  * And in 32kHz clocking mode the USART can only work at 9600 baudrate or at the baudrate that
405  * 9600 can evenly divide, eg: 4800, 3200.
406  *
407  * @param base USART peripheral base address.
408  * @param baudRate_Bps USART baudrate to be set..
409  * @param enableMode32k true is 32k mode, false is normal mode.
410  * @param srcClock_Hz USART clock source frequency in HZ.
411  * @retval kStatus_USART_BaudrateNotSupport Baudrate is not support in current clock source.
412  * @retval kStatus_Success Set baudrate succeed.
413  * @retval kStatus_InvalidArgument One or more arguments are invalid.
414  */
415 status_t USART_Enable32kMode(USART_Type *base, uint32_t baudRate_Bps, bool enableMode32k, uint32_t srcClock_Hz);
416 
417 /*!
418  * @brief Enable 9-bit data mode for USART.
419  *
420  * This function set the 9-bit mode for USART module. The 9th bit is not used for parity thus can be modified by user.
421  *
422  * @param base USART peripheral base address.
423  * @param enable true to enable, false to disable.
424  */
425 void USART_Enable9bitMode(USART_Type *base, bool enable);
426 
427 /*!
428  * @brief Set the USART slave address.
429  *
430  * This function configures the address for USART module that works as slave in 9-bit data mode. When the address
431  * detection is enabled, the frame it receices with MSB being 1 is considered as an address frame, otherwise it is
432  * considered as data frame. Once the address frame matches slave's own addresses, this slave is addressed. This
433  * address frame and its following data frames are stored in the receive buffer, otherwise the frames will be discarded.
434  * To un-address a slave, just send an address frame with unmatched address.
435  *
436  * @note Any USART instance joined in the multi-slave system can work as slave. The position of the address mark is the
437  * same as the parity bit when parity is enabled for 8 bit and 9 bit data formats.
438  *
439  * @param base USART peripheral base address.
440  * @param address USART slave address.
441  */
USART_SetMatchAddress(USART_Type * base,uint8_t address)442 static inline void USART_SetMatchAddress(USART_Type *base, uint8_t address)
443 {
444     /* Configure match address. */
445     base->ADDR = (uint32_t)address;
446 }
447 
448 /*!
449  * @brief Enable the USART match address feature.
450  *
451  * @param base USART peripheral base address.
452  * @param match true to enable match address, false to disable.
453  */
USART_EnableMatchAddress(USART_Type * base,bool match)454 static inline void USART_EnableMatchAddress(USART_Type *base, bool match)
455 {
456     /* Configure match address enable bit. */
457     if (match)
458     {
459         base->CFG |= (uint32_t)USART_CFG_AUTOADDR_MASK;
460         base->CTL |= (uint32_t)USART_CTL_ADDRDET_MASK;
461     }
462     else
463     {
464         base->CFG &= ~(uint32_t)USART_CFG_AUTOADDR_MASK;
465         base->CTL &= ~(uint32_t)USART_CTL_ADDRDET_MASK;
466     }
467 }
468 
469 /*! @} */
470 
471 /*!
472  * @name Status
473  * @{
474  */
475 
476 /*!
477  * @brief Get USART status flags.
478  *
479  * This function get all USART status flags, the flags are returned as the logical
480  * OR value of the enumerators @ref _usart_flags. To check a specific status,
481  * compare the return value with enumerators in @ref _usart_flags.
482  * For example, to check whether the TX is empty:
483  * @code
484  *     if (kUSART_TxFifoNotFullFlag & USART_GetStatusFlags(USART1))
485  *     {
486  *         ...
487  *     }
488  * @endcode
489  *
490  * @param base USART peripheral base address.
491  * @return USART status flags which are ORed by the enumerators in the _usart_flags.
492  */
USART_GetStatusFlags(USART_Type * base)493 static inline uint32_t USART_GetStatusFlags(USART_Type *base)
494 {
495     return (base->FIFOSTAT & 0xFF0000FFUL) | (base->STAT & 0xFFUL) << 16U | (base->STAT & 0xFFFF00UL);
496 }
497 
498 /*!
499  * @brief Clear USART status flags.
500  *
501  * This function clear supported USART status flags
502  * Flags that can be cleared or set are:
503  *      kUSART_TxError
504  *      kUSART_RxError
505  * For example:
506  * @code
507  *     USART_ClearStatusFlags(USART1, kUSART_TxError | kUSART_RxError)
508  * @endcode
509  *
510  * @param base USART peripheral base address.
511  * @param mask status flags to be cleared.
512  */
USART_ClearStatusFlags(USART_Type * base,uint32_t mask)513 static inline void USART_ClearStatusFlags(USART_Type *base, uint32_t mask)
514 {
515     mask &= (uint32_t)kUSART_AllClearFlags;
516     /* Clear the clearable status in STAT register. */
517     base->STAT = (mask & 0xFFFF00UL) | ((mask & 0xFF0000UL) >> 16U);
518     /* Only TXERR, RXERR fields support write. Remaining fields should be set to zero */
519     base->FIFOSTAT = mask & (USART_FIFOSTAT_TXERR_MASK | USART_FIFOSTAT_RXERR_MASK);
520 }
521 
522 /*! @} */
523 
524 /*!
525  * @name Interrupts
526  * @{
527  */
528 /*!
529  * @brief Enables USART interrupts according to the provided mask.
530  *
531  * This function enables the USART interrupts according to the provided mask. The mask
532  * is a logical OR of enumeration members. See @ref _usart_interrupt_enable.
533  * For example, to enable TX empty interrupt and RX full interrupt:
534  * @code
535  *     USART_EnableInterrupts(USART1, kUSART_TxLevelInterruptEnable | kUSART_RxLevelInterruptEnable);
536  * @endcode
537  *
538  * @param base USART peripheral base address.
539  * @param mask The interrupts to enable. Logical OR of @ref _usart_interrupt_enable.
540  */
USART_EnableInterrupts(USART_Type * base,uint32_t mask)541 static inline void USART_EnableInterrupts(USART_Type *base, uint32_t mask)
542 {
543     mask &= (uint32_t)kUSART_AllInterruptEnables;
544     base->INTENSET     = (mask & 0x1FF00UL) | ((mask & 0xFF0000UL) >> 16U);
545     base->FIFOINTENSET = mask & 0xF00000FUL;
546 }
547 
548 /*!
549  * @brief Disables USART interrupts according to a provided mask.
550  *
551  * This function disables the USART interrupts according to a provided mask. The mask
552  * is a logical OR of enumeration members. See @ref _usart_interrupt_enable.
553  * This example shows how to disable the TX empty interrupt and RX full interrupt:
554  * @code
555  *     USART_DisableInterrupts(USART1, kUSART_TxLevelInterruptEnable | kUSART_RxLevelInterruptEnable);
556  * @endcode
557  *
558  * @param base USART peripheral base address.
559  * @param mask The interrupts to disable. Logical OR of @ref _usart_interrupt_enable.
560  */
USART_DisableInterrupts(USART_Type * base,uint32_t mask)561 static inline void USART_DisableInterrupts(USART_Type *base, uint32_t mask)
562 {
563     mask &= (uint32_t)kUSART_AllInterruptEnables;
564     base->INTENCLR     = (mask & 0x1FF00UL) | ((mask & 0xFF0000UL) >> 16U);
565     base->FIFOINTENCLR = mask & 0xFUL;
566 }
567 
568 /*!
569  * @brief Returns enabled USART interrupts.
570  *
571  * This function returns the enabled USART interrupts.
572  *
573  * @param base USART peripheral base address.
574  */
USART_GetEnabledInterrupts(USART_Type * base)575 static inline uint32_t USART_GetEnabledInterrupts(USART_Type *base)
576 {
577     return (base->INTENSET & 0x1FF00UL) | ((base->INTENSET & 0xFFUL) << 16UL) | (base->FIFOINTENSET & 0xFUL);
578 }
579 
580 /*!
581  * @brief Enable DMA for Tx
582  */
USART_EnableTxDMA(USART_Type * base,bool enable)583 static inline void USART_EnableTxDMA(USART_Type *base, bool enable)
584 {
585     if (enable)
586     {
587         base->FIFOCFG |= USART_FIFOCFG_DMATX_MASK;
588     }
589     else
590     {
591         base->FIFOCFG &= ~(USART_FIFOCFG_DMATX_MASK);
592     }
593 }
594 
595 /*!
596  * @brief Enable DMA for Rx
597  */
USART_EnableRxDMA(USART_Type * base,bool enable)598 static inline void USART_EnableRxDMA(USART_Type *base, bool enable)
599 {
600     if (enable)
601     {
602         base->FIFOCFG |= USART_FIFOCFG_DMARX_MASK;
603     }
604     else
605     {
606         base->FIFOCFG &= ~(USART_FIFOCFG_DMARX_MASK);
607     }
608 }
609 
610 /*!
611  * @brief Enable CTS.
612  * This function will determine whether CTS is used for flow control.
613  *
614  * @param base    USART peripheral base address.
615  * @param enable  Enable CTS or not, true for enable and false for disable.
616  */
USART_EnableCTS(USART_Type * base,bool enable)617 static inline void USART_EnableCTS(USART_Type *base, bool enable)
618 {
619     if (enable)
620     {
621         base->CFG |= USART_CFG_CTSEN_MASK;
622     }
623     else
624     {
625         base->CFG &= ~USART_CFG_CTSEN_MASK;
626     }
627 }
628 
629 /*!
630  * @brief Continuous Clock generation.
631  * By default, SCLK is only output while data is being transmitted in synchronous mode.
632  * Enable this funciton, SCLK will run continuously in synchronous mode, allowing
633  * characters to be received on Un_RxD independently from transmission on Un_TXD).
634  *
635  * @param base    USART peripheral base address.
636  * @param enable  Enable Continuous Clock generation mode or not, true for enable and false for disable.
637  */
USART_EnableContinuousSCLK(USART_Type * base,bool enable)638 static inline void USART_EnableContinuousSCLK(USART_Type *base, bool enable)
639 {
640     if (enable)
641     {
642         base->CTL |= USART_CTL_CC_MASK;
643     }
644     else
645     {
646         base->CTL &= ~USART_CTL_CC_MASK;
647     }
648 }
649 
650 /*!
651  * @brief Enable Continuous Clock generation bit auto clear.
652  * While enable this cuntion, the Continuous Clock bit is automatically cleared when a complete
653  * character has been received. This bit is cleared at the same time.
654  *
655  * @param base    USART peripheral base address.
656  * @param enable  Enable auto clear or not, true for enable and false for disable.
657  */
USART_EnableAutoClearSCLK(USART_Type * base,bool enable)658 static inline void USART_EnableAutoClearSCLK(USART_Type *base, bool enable)
659 {
660     if (enable)
661     {
662         base->CTL |= USART_CTL_CLRCCONRX_MASK;
663     }
664     else
665     {
666         base->CTL &= ~USART_CTL_CLRCCONRX_MASK;
667     }
668 }
669 
670 /*!
671  * @brief Sets the rx FIFO watermark.
672  *
673  * @param base USART peripheral base address.
674  * @param water Rx FIFO watermark.
675  */
USART_SetRxFifoWatermark(USART_Type * base,uint8_t water)676 static inline void USART_SetRxFifoWatermark(USART_Type *base, uint8_t water)
677 {
678     assert(water <= (USART_FIFOTRIG_RXLVL_MASK >> USART_FIFOTRIG_RXLVL_SHIFT));
679     base->FIFOTRIG = (base->FIFOTRIG & ~USART_FIFOTRIG_RXLVL_MASK) | USART_FIFOTRIG_RXLVL(water);
680 }
681 
682 /*!
683  * @brief Sets the tx FIFO watermark.
684  *
685  * @param base USART peripheral base address.
686  * @param water Tx FIFO watermark.
687  */
USART_SetTxFifoWatermark(USART_Type * base,uint8_t water)688 static inline void USART_SetTxFifoWatermark(USART_Type *base, uint8_t water)
689 {
690     assert(water <= (USART_FIFOTRIG_TXLVL_MASK >> USART_FIFOTRIG_TXLVL_SHIFT));
691     base->FIFOTRIG = (base->FIFOTRIG & ~USART_FIFOTRIG_TXLVL_MASK) | USART_FIFOTRIG_TXLVL(water);
692 }
693 /*! @} */
694 
695 /*!
696  * @name Bus Operations
697  * @{
698  */
699 
700 /*!
701  * @brief Writes to the FIFOWR register.
702  *
703  * This function writes data to the txFIFO directly. The upper layer must ensure
704  * that txFIFO has space for data to write before calling this function.
705  *
706  * @param base USART peripheral base address.
707  * @param data The byte to write.
708  */
USART_WriteByte(USART_Type * base,uint8_t data)709 static inline void USART_WriteByte(USART_Type *base, uint8_t data)
710 {
711     base->FIFOWR = data;
712 }
713 
714 /*!
715  * @brief Reads the FIFORD register directly.
716  *
717  * This function reads data from the rxFIFO directly. The upper layer must
718  * ensure that the rxFIFO is not empty before calling this function.
719  *
720  * @param base USART peripheral base address.
721  * @return The byte read from USART data register.
722  */
USART_ReadByte(USART_Type * base)723 static inline uint8_t USART_ReadByte(USART_Type *base)
724 {
725     return (uint8_t)base->FIFORD;
726 }
727 
728 /*!
729  * @brief Gets the rx FIFO data count.
730  *
731  * @param base USART peripheral base address.
732  * @return rx FIFO data count.
733  */
USART_GetRxFifoCount(USART_Type * base)734 static inline uint8_t USART_GetRxFifoCount(USART_Type *base)
735 {
736     return (uint8_t)((base->FIFOSTAT & USART_FIFOSTAT_RXLVL_MASK) >> USART_FIFOSTAT_RXLVL_SHIFT);
737 }
738 
739 /*!
740  * @brief Gets the tx FIFO data count.
741  *
742  * @param base USART peripheral base address.
743  * @return tx FIFO data count.
744  */
USART_GetTxFifoCount(USART_Type * base)745 static inline uint8_t USART_GetTxFifoCount(USART_Type *base)
746 {
747     return (uint8_t)((base->FIFOSTAT & USART_FIFOSTAT_TXLVL_MASK) >> USART_FIFOSTAT_TXLVL_SHIFT);
748 }
749 
750 /*!
751  * @brief Transmit an address frame in 9-bit data mode.
752  *
753  * @param base USART peripheral base address.
754  * @param address USART slave address.
755  */
756 void USART_SendAddress(USART_Type *base, uint8_t address);
757 
758 /*!
759  * @brief Writes to the TX register using a blocking method.
760  *
761  * This function polls the TX register, waits for the TX register to be empty or for the TX FIFO
762  * to have room and writes data to the TX buffer.
763  *
764  * @param base USART peripheral base address.
765  * @param data Start address of the data to write.
766  * @param length Size of the data to write.
767  * @retval kStatus_USART_Timeout Transmission timed out and was aborted.
768  * @retval kStatus_InvalidArgument Invalid argument.
769  * @retval kStatus_Success Successfully wrote all data.
770  */
771 status_t USART_WriteBlocking(USART_Type *base, const uint8_t *data, size_t length);
772 
773 /*!
774  * @brief Read RX data register using a blocking method.
775  *
776  * This function polls the RX register, waits for the RX register to be full or for RX FIFO to
777  * have data and read data from the TX register.
778  *
779  * @param base USART peripheral base address.
780  * @param data Start address of the buffer to store the received data.
781  * @param length Size of the buffer.
782  * @retval kStatus_USART_FramingError Receiver overrun happened while receiving data.
783  * @retval kStatus_USART_ParityError Noise error happened while receiving data.
784  * @retval kStatus_USART_NoiseError Framing error happened while receiving data.
785  * @retval kStatus_USART_RxError Overflow or underflow rxFIFO happened.
786  * @retval kStatus_USART_Timeout Transmission timed out and was aborted.
787  * @retval kStatus_Success Successfully received all data.
788  */
789 status_t USART_ReadBlocking(USART_Type *base, uint8_t *data, size_t length);
790 
791 /*! @} */
792 
793 /*!
794  * @name Transactional
795  * @{
796  */
797 
798 /*!
799  * @brief Initializes the USART handle.
800  *
801  * This function initializes the USART handle which can be used for other USART
802  * transactional APIs. Usually, for a specified USART instance,
803  * call this API once to get the initialized handle.
804  *
805  * @param base USART peripheral base address.
806  * @param handle USART handle pointer.
807  * @param callback The callback function.
808  * @param userData The parameter of the callback function.
809  */
810 status_t USART_TransferCreateHandle(USART_Type *base,
811                                     usart_handle_t *handle,
812                                     usart_transfer_callback_t callback,
813                                     void *userData);
814 
815 /*!
816  * @brief Transmits a buffer of data using the interrupt method.
817  *
818  * This function sends data using an interrupt method. This is a non-blocking function, which
819  * returns directly without waiting for all data to be written to the TX register. When
820  * all data is written to the TX register in the IRQ handler, the USART driver calls the callback
821  * function and passes the @ref kStatus_USART_TxIdle as status parameter.
822  *
823  * @param base USART peripheral base address.
824  * @param handle USART handle pointer.
825  * @param xfer USART transfer structure. See  #usart_transfer_t.
826  * @retval kStatus_Success Successfully start the data transmission.
827  * @retval kStatus_USART_TxBusy Previous transmission still not finished, data not all written to TX register yet.
828  * @retval kStatus_InvalidArgument Invalid argument.
829  */
830 status_t USART_TransferSendNonBlocking(USART_Type *base, usart_handle_t *handle, usart_transfer_t *xfer);
831 
832 /*!
833  * @brief Sets up the RX ring buffer.
834  *
835  * This function sets up the RX ring buffer to a specific USART handle.
836  *
837  * When the RX ring buffer is used, data received are stored into the ring buffer even when the
838  * user doesn't call the USART_TransferReceiveNonBlocking() API. If there is already data received
839  * in the ring buffer, the user can get the received data from the ring buffer directly.
840  *
841  * @note When using the RX ring buffer, one byte is reserved for internal use. In other
842  * words, if @p ringBufferSize is 32, then only 31 bytes are used for saving data.
843  *
844  * @param base USART peripheral base address.
845  * @param handle USART handle pointer.
846  * @param ringBuffer Start address of the ring buffer for background receiving. Pass NULL to disable the ring buffer.
847  * @param ringBufferSize size of the ring buffer.
848  */
849 void USART_TransferStartRingBuffer(USART_Type *base,
850                                    usart_handle_t *handle,
851                                    uint8_t *ringBuffer,
852                                    size_t ringBufferSize);
853 
854 /*!
855  * @brief Aborts the background transfer and uninstalls the ring buffer.
856  *
857  * This function aborts the background transfer and uninstalls the ring buffer.
858  *
859  * @param base USART peripheral base address.
860  * @param handle USART handle pointer.
861  */
862 void USART_TransferStopRingBuffer(USART_Type *base, usart_handle_t *handle);
863 
864 /*!
865  * @brief Get the length of received data in RX ring buffer.
866  *
867  * @param handle USART handle pointer.
868  * @return Length of received data in RX ring buffer.
869  */
870 size_t USART_TransferGetRxRingBufferLength(usart_handle_t *handle);
871 
872 /*!
873  * @brief Aborts the interrupt-driven data transmit.
874  *
875  * This function aborts the interrupt driven data sending. The user can get the remainBtyes to find out
876  * how many bytes are still not sent out.
877  *
878  * @param base USART peripheral base address.
879  * @param handle USART handle pointer.
880  */
881 void USART_TransferAbortSend(USART_Type *base, usart_handle_t *handle);
882 
883 /*!
884  * @brief Get the number of bytes that have been sent out to bus.
885  *
886  * This function gets the number of bytes that have been sent out to bus by interrupt method.
887  *
888  * @param base USART peripheral base address.
889  * @param handle USART handle pointer.
890  * @param count Send bytes count.
891  * @retval kStatus_NoTransferInProgress No send in progress.
892  * @retval kStatus_InvalidArgument Parameter is invalid.
893  * @retval kStatus_Success Get successfully through the parameter \p count;
894  */
895 status_t USART_TransferGetSendCount(USART_Type *base, usart_handle_t *handle, uint32_t *count);
896 
897 /*!
898  * @brief Receives a buffer of data using an interrupt method.
899  *
900  * This function receives data using an interrupt method. This is a non-blocking function, which
901  *  returns without waiting for all data to be received.
902  * If the RX ring buffer is used and not empty, the data in the ring buffer is copied and
903  * the parameter @p receivedBytes shows how many bytes are copied from the ring buffer.
904  * After copying, if the data in the ring buffer is not enough to read, the receive
905  * request is saved by the USART driver. When the new data arrives, the receive request
906  * is serviced first. When all data is received, the USART driver notifies the upper layer
907  * through a callback function and passes the status parameter @ref kStatus_USART_RxIdle.
908  * For example, the upper layer needs 10 bytes but there are only 5 bytes in the ring buffer.
909  * The 5 bytes are copied to the xfer->data and this function returns with the
910  * parameter @p receivedBytes set to 5. For the left 5 bytes, newly arrived data is
911  * saved from the xfer->data[5]. When 5 bytes are received, the USART driver notifies the upper layer.
912  * If the RX ring buffer is not enabled, this function enables the RX and RX interrupt
913  * to receive data to the xfer->data. When all data is received, the upper layer is notified.
914  *
915  * @param base USART peripheral base address.
916  * @param handle USART handle pointer.
917  * @param xfer USART transfer structure, see #usart_transfer_t.
918  * @param receivedBytes Bytes received from the ring buffer directly.
919  * @retval kStatus_Success Successfully queue the transfer into transmit queue.
920  * @retval kStatus_USART_RxBusy Previous receive request is not finished.
921  * @retval kStatus_InvalidArgument Invalid argument.
922  */
923 status_t USART_TransferReceiveNonBlocking(USART_Type *base,
924                                           usart_handle_t *handle,
925                                           usart_transfer_t *xfer,
926                                           size_t *receivedBytes);
927 
928 /*!
929  * @brief Aborts the interrupt-driven data receiving.
930  *
931  * This function aborts the interrupt-driven data receiving. The user can get the remainBytes to find out
932  * how many bytes not received yet.
933  *
934  * @param base USART peripheral base address.
935  * @param handle USART handle pointer.
936  */
937 void USART_TransferAbortReceive(USART_Type *base, usart_handle_t *handle);
938 
939 /*!
940  * @brief Get the number of bytes that have been received.
941  *
942  * This function gets the number of bytes that have been received.
943  *
944  * @param base USART peripheral base address.
945  * @param handle USART handle pointer.
946  * @param count Receive bytes count.
947  * @retval kStatus_NoTransferInProgress No receive in progress.
948  * @retval kStatus_InvalidArgument Parameter is invalid.
949  * @retval kStatus_Success Get successfully through the parameter \p count;
950  */
951 status_t USART_TransferGetReceiveCount(USART_Type *base, usart_handle_t *handle, uint32_t *count);
952 
953 /*!
954  * @brief USART IRQ handle function.
955  *
956  * This function handles the USART transmit and receive IRQ request.
957  *
958  * @param base USART peripheral base address.
959  * @param handle USART handle pointer.
960  */
961 void USART_TransferHandleIRQ(USART_Type *base, usart_handle_t *handle);
962 
963 /*! @} */
964 
965 #if defined(__cplusplus)
966 }
967 #endif
968 
969 /*! @}*/
970 
971 #endif /* FSL_USART_H_ */
972