1 /***************************************************************************//**
2 * @file
3 * @brief Low Energy Universal Asynchronous Receiver/Transmitter (LEUART)
4 * Peripheral API
5 *******************************************************************************
6 * # License
7 * <b>Copyright 2018 Silicon Laboratories Inc. www.silabs.com</b>
8 *******************************************************************************
9 *
10 * SPDX-License-Identifier: Zlib
11 *
12 * The licensor of this software is Silicon Laboratories Inc.
13 *
14 * This software is provided 'as-is', without any express or implied
15 * warranty. In no event will the authors be held liable for any damages
16 * arising from the use of this software.
17 *
18 * Permission is granted to anyone to use this software for any purpose,
19 * including commercial applications, and to alter it and redistribute it
20 * freely, subject to the following restrictions:
21 *
22 * 1. The origin of this software must not be misrepresented; you must not
23 * claim that you wrote the original software. If you use this software
24 * in a product, an acknowledgment in the product documentation would be
25 * appreciated but is not required.
26 * 2. Altered source versions must be plainly marked as such, and must not be
27 * misrepresented as being the original software.
28 * 3. This notice may not be removed or altered from any source distribution.
29 *
30 ******************************************************************************/
31
32 #include "em_leuart.h"
33 #if defined(LEUART_COUNT) && (LEUART_COUNT > 0)
34
35 #include "em_cmu.h"
36 #include "em_assert.h"
37
38 /***************************************************************************//**
39 * @addtogroup leuart LEUART - Low Energy UART
40 * @brief Low Energy Universal Asynchronous Receiver/Transmitter (LEUART)
41 * Peripheral API
42 * @details
43 * This module contains functions to control the LEUART peripheral of Silicon
44 * Labs 32-bit MCUs and SoCs. The LEUART module provides the full UART communication using
45 * a low frequency 32.768 kHz clock and has special features for communication
46 * without the CPU intervention.
47 * @{
48 ******************************************************************************/
49
50 /*******************************************************************************
51 ******************************* DEFINES ***********************************
52 ******************************************************************************/
53
54 /** @cond DO_NOT_INCLUDE_WITH_DOXYGEN */
55
56 /** A validation of the LEUART register block pointer reference
57 * for assert statements. */
58 #if (LEUART_COUNT == 1)
59 #define LEUART_REF_VALID(ref) ((ref) == LEUART0)
60 #elif (LEUART_COUNT == 2)
61 #define LEUART_REF_VALID(ref) (((ref) == LEUART0) || ((ref) == LEUART1))
62 #else
63 #error "Undefined number of low energy UARTs (LEUART)."
64 #endif
65
66 /** @endcond */
67
68 /*******************************************************************************
69 ************************** LOCAL FUNCTIONS ********************************
70 ******************************************************************************/
71
72 /** @cond DO_NOT_INCLUDE_WITH_DOXYGEN */
73
74 /***************************************************************************//**
75 * @brief
76 * Wait for ongoing sync of register(s) to the low-frequency domain to complete.
77 *
78 * @param[in] leuart
79 * A pointer to the LEUART peripheral register block.
80 *
81 * @param[in] mask
82 * A bitmask corresponding to SYNCBUSY register defined bits, indicating
83 * registers that must complete any ongoing synchronization.
84 ******************************************************************************/
LEUART_Sync(LEUART_TypeDef * leuart,uint32_t mask)85 __STATIC_INLINE void LEUART_Sync(LEUART_TypeDef *leuart, uint32_t mask)
86 {
87 /* Avoid deadlock if modifying the same register twice when freeze mode is */
88 /* activated. */
89 if (leuart->FREEZE & LEUART_FREEZE_REGFREEZE) {
90 return;
91 }
92
93 /* Wait for any pending previous write operation to have been completed */
94 /* in the low-frequency domai. */
95 while ((leuart->SYNCBUSY & mask) != 0U) {
96 }
97 }
98
99 /** @endcond */
100
101 /*******************************************************************************
102 ************************** GLOBAL FUNCTIONS *******************************
103 ******************************************************************************/
104
105 /***************************************************************************//**
106 * @brief
107 * Calculate the baudrate for the LEUART given reference frequency and clock division.
108 *
109 * @details
110 * This function returns the baudrate that a LEUART module will use if
111 * configured with the given frequency and clock divisor. Notice that
112 * this function will not use the hardware configuration. It can be used
113 * to determine if a given configuration is sufficiently accurate for the
114 * application.
115 *
116 * @param[in] refFreq
117 * The LEUART peripheral frequency used.
118 *
119 * @param[in] clkdiv
120 * The clock division factor to be used.
121 *
122 * @return
123 * A baudrate with given settings.
124 ******************************************************************************/
LEUART_BaudrateCalc(uint32_t refFreq,uint32_t clkdiv)125 uint32_t LEUART_BaudrateCalc(uint32_t refFreq, uint32_t clkdiv)
126 {
127 uint32_t divisor;
128 uint32_t remainder;
129 uint32_t quotient;
130 uint32_t br;
131
132 /* Mask out unused bits. */
133 clkdiv &= _LEUART_CLKDIV_MASK;
134
135 /* Use integer division to avoid forcing in float division */
136 /* utils, and yet keep rounding effect errors to a minimum. */
137
138 /*
139 * Baudrate is given by:
140 *
141 * br = fLEUARTn/(1 + (CLKDIV / 256))
142 *
143 * which can be rewritten to
144 *
145 * br = (256 * fLEUARTn)/(256 + CLKDIV)
146 *
147 * Normally, with fLEUARTn appr 32768 Hz, there is no problem with overflow
148 * if using 32 bit arithmetic. However, since fLEUARTn may be derived from
149 * HFCORECLK, consider the overflow when using integer arithmetic.
150 */
151
152 /*
153 * The basic problem with integer division in the above formula is that
154 * the dividend (256 * fLEUARTn) may become higher than the maximum 32 bit
155 * integer. Yet we want to evaluate the dividend first before dividing
156 * to get as small rounding effects as possible.
157 * Also, harsh restrictions should be avoided on the maximum fLEUARTn value.
158 *
159 * For division a/b:
160 *
161 * a = qb + r
162 *
163 * where q is the quotient and r is the remainder, both integers.
164 *
165 * The orignal baudrate formula can be rewritten as:
166 *
167 * br = 256a / b = 256(qb + r)/b = 256q + 256r/b
168 *
169 * where a is 'refFreq' and b is 'divisor', referring to variable names.
170 */
171
172 divisor = 256 + clkdiv;
173 quotient = refFreq / divisor;
174 remainder = refFreq % divisor;
175
176 /* Since the divisor >= 256, the below cannot exceed the maximum 32 bit value. */
177 br = 256 * quotient;
178
179 /*
180 * A remainder < (256 + clkdiv), which means the dividend (256 * remainder) worst case is
181 * 256*(256 + 0x7ff8) = 0x80F800.
182 */
183 br += (256 * remainder) / divisor;
184
185 return br;
186 }
187
188 /***************************************************************************//**
189 * @brief
190 * Get the current baudrate for LEUART.
191 *
192 * @details
193 * This function returns the actual baudrate (not considering the oscillator
194 * inaccuracies) used by the LEUART peripheral.
195 *
196 * @param[in] leuart
197 * A pointer to the LEUART peripheral register block.
198 *
199 * @return
200 * The current baudrate.
201 ******************************************************************************/
LEUART_BaudrateGet(LEUART_TypeDef * leuart)202 uint32_t LEUART_BaudrateGet(LEUART_TypeDef *leuart)
203 {
204 uint32_t freq;
205 CMU_Clock_TypeDef clock;
206
207 /* Get the current frequency. */
208 if (leuart == LEUART0) {
209 clock = cmuClock_LEUART0;
210 }
211 #if (LEUART_COUNT > 1)
212 else if (leuart == LEUART1) {
213 clock = cmuClock_LEUART1;
214 }
215 #endif
216 else {
217 EFM_ASSERT(0);
218 return 0;
219 }
220
221 freq = CMU_ClockFreqGet(clock);
222
223 return LEUART_BaudrateCalc(freq, leuart->CLKDIV);
224 }
225
226 /***************************************************************************//**
227 * @brief
228 * Configure the baudrate (or as close as possible to a specified baudrate).
229 *
230 * @note
231 * The baudrate setting requires synchronization into the
232 * low-frequency domain. If the same register is modified before a previous
233 * update has completed, this function will stall until the previous
234 * synchronization has completed.
235 *
236 * @param[in] leuart
237 * A pointer to the LEUART peripheral register block.
238 *
239 * @param[in] refFreq
240 * The LEUART reference clock frequency in Hz that will be used. If set to 0,
241 * the currently configured reference clock is assumed.
242 *
243 * @param[in] baudrate
244 * A baudrate to try to achieve for LEUART.
245 ******************************************************************************/
LEUART_BaudrateSet(LEUART_TypeDef * leuart,uint32_t refFreq,uint32_t baudrate)246 void LEUART_BaudrateSet(LEUART_TypeDef *leuart,
247 uint32_t refFreq,
248 uint32_t baudrate)
249 {
250 uint32_t clkdiv;
251 CMU_Clock_TypeDef clock;
252
253 /* Prevent dividing by 0. */
254 EFM_ASSERT(baudrate);
255
256 /*
257 * Use integer division to avoid forcing in float division
258 * utils, and yet keep rounding effect errors to a minimum.
259 *
260 * CLKDIV in asynchronous mode is given by:
261 *
262 * CLKDIV = 256*(fLEUARTn/br - 1) = ((256*fLEUARTn)/br) - 256
263 *
264 * Normally, with fLEUARTn appr 32768 Hz, there is no problem with overflow
265 * if using 32 bit arithmetic. However, since fLEUARTn may be derived from
266 * HFCORECLK, consider the overflow when using integer arithmetic.
267 *
268 * The basic problem with integer division in the above formula is that
269 * the dividend (256 * fLEUARTn) may become higher than the maximum 32 bit
270 * integer. Yet, the dividend should be evaluated first before dividing
271 * to get as small rounding effects as possible.
272 * Also, harsh restrictions on the maximum fLEUARTn value should not be made.
273 *
274 * Since the last 3 bits of CLKDIV are don't care, base the
275 * integer arithmetic on the below formula:
276 *
277 * CLKDIV/8 = ((32*fLEUARTn)/br) - 32
278 *
279 * and calculate 1/8 of CLKDIV first. This allows for fLEUARTn
280 * up to 128 MHz without overflowing a 32 bit value.
281 */
282
283 /* Get the current frequency. */
284 if (!refFreq) {
285 if (leuart == LEUART0) {
286 clock = cmuClock_LEUART0;
287 }
288 #if (LEUART_COUNT > 1)
289 else if (leuart == LEUART1) {
290 clock = cmuClock_LEUART1;
291 }
292 #endif
293 else {
294 EFM_ASSERT(0);
295 return;
296 }
297
298 refFreq = CMU_ClockFreqGet(clock);
299 }
300
301 /* Calculate and set the CLKDIV with fractional bits. */
302 clkdiv = (32 * refFreq) / baudrate;
303 clkdiv -= 32;
304 clkdiv *= 8;
305
306 /* Verify that the resulting clock divider is within limits. */
307 EFM_ASSERT(clkdiv <= _LEUART_CLKDIV_MASK);
308
309 /* If the EFM_ASSERT is not enabled, make sure not to write to reserved bits. */
310 clkdiv &= _LEUART_CLKDIV_MASK;
311
312 /* LF register about to be modified requires sync; busy check. */
313 LEUART_Sync(leuart, LEUART_SYNCBUSY_CLKDIV);
314
315 leuart->CLKDIV = clkdiv;
316 }
317
318 /***************************************************************************//**
319 * @brief
320 * Enable/disable the LEUART receiver and/or transmitter.
321 *
322 * @details
323 * Notice that this function does not do any configuration. Enabling should
324 * normally be done after the initialization is done (if not enabled as part
325 * of initialization).
326 *
327 * @note
328 * Enabling/disabling requires synchronization into the low-frequency domain.
329 * If the same register is modified before a previous update has completed,
330 * this function will stall until the previous synchronization has completed.
331 *
332 * @param[in] leuart
333 * A pointer to the LEUART peripheral register block.
334 *
335 * @param[in] enable
336 * Select status for receiver/transmitter.
337 ******************************************************************************/
LEUART_Enable(LEUART_TypeDef * leuart,LEUART_Enable_TypeDef enable)338 void LEUART_Enable(LEUART_TypeDef *leuart, LEUART_Enable_TypeDef enable)
339 {
340 uint32_t tmp;
341
342 /* Make sure that the module exists on the selected chip. */
343 EFM_ASSERT(LEUART_REF_VALID(leuart));
344
345 /* Disable as specified. */
346 tmp = ~((uint32_t)(enable));
347 tmp &= (_LEUART_CMD_RXEN_MASK | _LEUART_CMD_TXEN_MASK);
348 tmp <<= 1;
349 /* Enable as specified. */
350 tmp |= (uint32_t)(enable);
351
352 /* LF register about to be modified requires sync; busy check. */
353 LEUART_Sync(leuart, LEUART_SYNCBUSY_CMD);
354
355 leuart->CMD = tmp;
356 }
357
358 /***************************************************************************//**
359 * @brief
360 * LEUART register synchronization freeze control.
361 *
362 * @details
363 * Some LEUART registers require synchronization into the low-frequency (LF)
364 * domain. The freeze feature allows for several such registers to be
365 * modified before passing them to the LF domain simultaneously (which
366 * takes place when the freeze mode is disabled).
367 *
368 * @note
369 * When enabling freeze mode, this function will wait for all current
370 * ongoing LEUART synchronization to the LF domain to complete (Normally
371 * synchronization will not be in progress.) However, for this reason, when
372 * using freeze mode, modifications of registers requiring LF synchronization
373 * should be done within one freeze enable/disable block to avoid unnecessary
374 * stalling.
375 *
376 * @param[in] leuart
377 * A pointer to the LEUART peripheral register block.
378 *
379 * @param[in] enable
380 * @li True - enable freeze, modified registers are not propagated to the
381 * LF domain
382 * @li False - disables freeze, modified registers are propagated to the LF
383 * domain
384 ******************************************************************************/
LEUART_FreezeEnable(LEUART_TypeDef * leuart,bool enable)385 void LEUART_FreezeEnable(LEUART_TypeDef *leuart, bool enable)
386 {
387 if (enable) {
388 /*
389 * Wait for any ongoing LF synchronization to complete to
390 * protect against the rare case when a user
391 * - modifies a register requiring LF sync
392 * - then enables freeze before LF sync completed
393 * - then modifies the same register again
394 * since modifying a register while it is in sync progress should be
395 * avoided.
396 */
397 while (leuart->SYNCBUSY != 0U) {
398 }
399
400 leuart->FREEZE = LEUART_FREEZE_REGFREEZE;
401 } else {
402 leuart->FREEZE = 0;
403 }
404 }
405
406 /***************************************************************************//**
407 * @brief
408 * Initialize LEUART.
409 *
410 * @details
411 * This function will configure basic settings to operate in normal
412 * asynchronous mode. Consider using LEUART_Reset() prior to this function if
413 * the state of configuration is not known, since only configuration settings
414 * specified by @p init are set.
415 *
416 * Special control setup not covered by this function may be done either
417 * before or after using this function (but normally before enabling)
418 * by direct modification of the CTRL register.
419 *
420 * Notice that pins used by the LEUART module must be properly configured
421 * by the user explicitly for the LEUART to work as intended.
422 * (When configuring pins consider the sequence of
423 * configuration to avoid unintended pulses/glitches on output
424 * pins.)
425 *
426 * @note
427 * Initializing requires synchronization into the low-frequency domain.
428 * If the same register is modified before a previous update has completed,
429 * this function will stall until the previous synchronization has completed.
430 *
431 * @param[in] leuart
432 * A pointer to the LEUART peripheral register block.
433 *
434 * @param[in] init
435 * A pointer to the initialization structure used to configure basic async setup.
436 ******************************************************************************/
LEUART_Init(LEUART_TypeDef * leuart,LEUART_Init_TypeDef const * init)437 void LEUART_Init(LEUART_TypeDef *leuart, LEUART_Init_TypeDef const *init)
438 {
439 /* Make sure the module exists on the selected chip. */
440 EFM_ASSERT(LEUART_REF_VALID(leuart));
441
442 /* LF register about to be modified requires sync; busy check. */
443 LEUART_Sync(leuart, LEUART_SYNCBUSY_CMD);
444
445 /* Ensure disabled while configuring. */
446 leuart->CMD = LEUART_CMD_RXDIS | LEUART_CMD_TXDIS;
447
448 /* Freeze registers to avoid stalling for the LF synchronization. */
449 LEUART_FreezeEnable(leuart, true);
450
451 /* Configure databits and stopbits. */
452 leuart->CTRL = (leuart->CTRL & ~(_LEUART_CTRL_PARITY_MASK
453 | _LEUART_CTRL_STOPBITS_MASK))
454 | (uint32_t)(init->databits)
455 | (uint32_t)(init->parity)
456 | (uint32_t)(init->stopbits);
457
458 /* Configure the baudrate. */
459 LEUART_BaudrateSet(leuart, init->refFreq, init->baudrate);
460
461 /* Finally enable (as specified). */
462 leuart->CMD = (uint32_t)init->enable;
463
464 /* Unfreeze registers and pass new settings on to LEUART. */
465 LEUART_FreezeEnable(leuart, false);
466 }
467
468 /***************************************************************************//**
469 * @brief
470 * Reset LEUART to the same state that it was in after a hardware reset.
471 *
472 * @param[in] leuart
473 * A pointer to the LEUART peripheral register block.
474 ******************************************************************************/
LEUART_Reset(LEUART_TypeDef * leuart)475 void LEUART_Reset(LEUART_TypeDef *leuart)
476 {
477 /* Make sure the module exists on the selected chip. */
478 EFM_ASSERT(LEUART_REF_VALID(leuart));
479
480 /* Freeze registers to avoid stalling for LF synchronization. */
481 LEUART_FreezeEnable(leuart, true);
482
483 /* Make sure disabled first, before resetting other registers. */
484 leuart->CMD = LEUART_CMD_RXDIS | LEUART_CMD_TXDIS | LEUART_CMD_RXBLOCKDIS
485 | LEUART_CMD_CLEARTX | LEUART_CMD_CLEARRX;
486 leuart->CTRL = _LEUART_CTRL_RESETVALUE;
487 leuart->CLKDIV = _LEUART_CLKDIV_RESETVALUE;
488 leuart->STARTFRAME = _LEUART_STARTFRAME_RESETVALUE;
489 leuart->SIGFRAME = _LEUART_SIGFRAME_RESETVALUE;
490 leuart->IEN = _LEUART_IEN_RESETVALUE;
491 leuart->IFC = _LEUART_IFC_MASK;
492 leuart->PULSECTRL = _LEUART_PULSECTRL_RESETVALUE;
493 #if defined(_LEUART_ROUTEPEN_MASK)
494 leuart->ROUTEPEN = _LEUART_ROUTEPEN_RESETVALUE;
495 leuart->ROUTELOC0 = _LEUART_ROUTELOC0_RESETVALUE;
496 #else
497 leuart->ROUTE = _LEUART_ROUTE_RESETVALUE;
498 #endif
499
500 /* Unfreeze registers and pass new settings on to LEUART. */
501 LEUART_FreezeEnable(leuart, false);
502 }
503
504 /***************************************************************************//**
505 * @brief
506 * Receive one 8 bit frame, (or part of 9 bit frame).
507 *
508 * @details
509 * This function is normally used to receive one frame when operating with
510 * frame length 8 bits. See LEUART_RxExt() for reception of
511 * 9 bit frames.
512 *
513 * Notice that possible parity/stop bits are not considered a part of the specified
514 * frame bit length.
515 *
516 * @note
517 * This function will stall if the buffer is empty until data is received.
518 *
519 * @param[in] leuart
520 * A pointer to the LEUART peripheral register block.
521 *
522 * @return
523 * Data received.
524 ******************************************************************************/
LEUART_Rx(LEUART_TypeDef * leuart)525 uint8_t LEUART_Rx(LEUART_TypeDef *leuart)
526 {
527 while (!(leuart->STATUS & LEUART_STATUS_RXDATAV)) {
528 }
529
530 return (uint8_t)leuart->RXDATA;
531 }
532
533 /***************************************************************************//**
534 * @brief
535 * Receive one 8-9 bit frame with extended information.
536 *
537 * @details
538 * This function is normally used to receive one frame and additional RX
539 * status information is required.
540 *
541 * @note
542 * This function will stall if buffer is empty until data is received.
543 *
544 * @param[in] leuart
545 * A pointer to the LEUART peripheral register block.
546 *
547 * @return
548 * Data received.
549 ******************************************************************************/
LEUART_RxExt(LEUART_TypeDef * leuart)550 uint16_t LEUART_RxExt(LEUART_TypeDef *leuart)
551 {
552 while (!(leuart->STATUS & LEUART_STATUS_RXDATAV)) {
553 }
554
555 return (uint16_t)leuart->RXDATAX;
556 }
557
558 /***************************************************************************//**
559 * @brief
560 * Transmit one frame.
561 *
562 * @details
563 * Depending on the frame length configuration, 8 (least significant) bits from
564 * @p data are transmitted. If the frame length is 9, 8 bits are transmitted from
565 * @p data and one bit as specified by the CTRL register, BIT8DV field.
566 * See LEUART_TxExt() for transmitting 9 bit frame with full control of
567 * all 9 bits.
568 *
569 * Notice that possible parity/stop bits in asynchronous mode are not
570 * considered a part of the specified frame bit length.
571 *
572 * @note
573 * This function will stall if buffer is full until the buffer becomes available.
574 *
575 * @param[in] leuart
576 * A pointer to the LEUART peripheral register block.
577 *
578 * @param[in] data
579 * Data to transmit. See details above for more info.
580 ******************************************************************************/
LEUART_Tx(LEUART_TypeDef * leuart,uint8_t data)581 void LEUART_Tx(LEUART_TypeDef *leuart, uint8_t data)
582 {
583 /* Check that transmit buffer is empty. */
584 while (!(leuart->STATUS & LEUART_STATUS_TXBL)) {
585 }
586
587 /* LF register about to be modified requires sync; busy check. */
588 LEUART_Sync(leuart, LEUART_SYNCBUSY_TXDATA);
589
590 leuart->TXDATA = (uint32_t)data;
591 }
592
593 /***************************************************************************//**
594 * @brief
595 * Transmit one 8-9 bit frame with extended control.
596 *
597 * @details
598 * Notice that possible parity/stop bits in asynchronous mode are not
599 * considered a part of the specified frame bit length.
600 *
601 * @note
602 * This function will stall if the buffer is full until the buffer becomes available.
603 *
604 * @param[in] leuart
605 * A pointer to the LEUART peripheral register block.
606 *
607 * @param[in] data
608 * Data to transmit with extended control. Least significant bit contains
609 * frame bits and additional control bits are available as documented in
610 * the reference manual (set to 0 if not used).
611 ******************************************************************************/
LEUART_TxExt(LEUART_TypeDef * leuart,uint16_t data)612 void LEUART_TxExt(LEUART_TypeDef *leuart, uint16_t data)
613 {
614 /* Check that transmit buffer is empty. */
615 while (!(leuart->STATUS & LEUART_STATUS_TXBL)) {
616 }
617
618 /* LF register about to be modified requires sync; busy check. */
619 LEUART_Sync(leuart, LEUART_SYNCBUSY_TXDATAX);
620
621 leuart->TXDATAX = (uint32_t)data;
622 }
623
624 /***************************************************************************//**
625 * @brief
626 * Enables handling of LEUART TX by DMA in EM2.
627 *
628 * @param[in] leuart
629 * A pointer to the LEUART peripheral register block.
630 *
631 * @param[in] enable
632 * True - enables functionality
633 * False - disables functionality
634 *
635 ******************************************************************************/
LEUART_TxDmaInEM2Enable(LEUART_TypeDef * leuart,bool enable)636 void LEUART_TxDmaInEM2Enable(LEUART_TypeDef *leuart, bool enable)
637 {
638 /* LF register about to be modified requires sync; busy check. */
639 LEUART_Sync(leuart, LEUART_SYNCBUSY_CTRL | LEUART_SYNCBUSY_CMD);
640
641 #if defined(_SILICON_LABS_GECKO_INTERNAL_SDID_80)
642 /* LEUART_E201: Changing the value of TXDMAWU while TXEN=1 could potentially
643 * cause unpredictable behavior. */
644 bool txEnabled = (leuart->STATUS & _LEUART_STATUS_TXENS_MASK) != 0U;
645 if (txEnabled) {
646 /* Wait for potential transmit to complete. */
647 while ((leuart->STATUS & LEUART_STATUS_TXIDLE) == 0U) {
648 }
649
650 leuart->CMD = LEUART_CMD_TXDIS;
651 LEUART_Sync(leuart, LEUART_SYNCBUSY_CMD);
652 }
653
654 if (enable) {
655 leuart->CTRL |= LEUART_CTRL_TXDMAWU;
656 } else {
657 leuart->CTRL &= ~LEUART_CTRL_TXDMAWU;
658 }
659
660 if (txEnabled) {
661 leuart->CMD = LEUART_CMD_TXEN;
662 }
663 #else
664 if (enable) {
665 leuart->CTRL |= LEUART_CTRL_TXDMAWU;
666 } else {
667 leuart->CTRL &= ~LEUART_CTRL_TXDMAWU;
668 }
669 #endif
670 }
671
672 /***************************************************************************//**
673 * @brief
674 * Enables handling of LEUART RX by DMA in EM2.
675 *
676 * @param[in] leuart
677 * A pointer to the LEUART peripheral register block.
678 *
679 * @param[in] enable
680 * True - enables functionality
681 * False - disables functionality
682 *
683 ******************************************************************************/
LEUART_RxDmaInEM2Enable(LEUART_TypeDef * leuart,bool enable)684 void LEUART_RxDmaInEM2Enable(LEUART_TypeDef *leuart, bool enable)
685 {
686 /* LF register about to be modified requires sync; busy check. */
687 LEUART_Sync(leuart, LEUART_SYNCBUSY_CTRL | LEUART_SYNCBUSY_CMD);
688
689 #if defined(_SILICON_LABS_GECKO_INTERNAL_SDID_80)
690 /* LEUART_E201: Changing the value of RXDMAWU while RXEN=1 could potentially
691 * cause unpredictable behavior. */
692 bool rxEnabled = (leuart->STATUS & _LEUART_STATUS_RXENS_MASK) != 0U;
693
694 if (rxEnabled) {
695 leuart->CMD = LEUART_CMD_RXDIS;
696 LEUART_Sync(leuart, LEUART_SYNCBUSY_CMD);
697 }
698
699 if (enable) {
700 leuart->CTRL |= LEUART_CTRL_RXDMAWU;
701 } else {
702 leuart->CTRL &= ~LEUART_CTRL_RXDMAWU;
703 }
704
705 if (rxEnabled) {
706 leuart->CMD = LEUART_CMD_RXEN;
707 }
708 #else
709 if (enable) {
710 leuart->CTRL |= LEUART_CTRL_RXDMAWU;
711 } else {
712 leuart->CTRL &= ~LEUART_CTRL_RXDMAWU;
713 }
714 #endif
715 }
716
717 /** @} (end addtogroup leuart) */
718 #endif /* defined(LEUART_COUNT) && (LEUART_COUNT > 0) */
719