1 /*
2  * Copyright (c) 2015, Freescale Semiconductor, Inc.
3  * Copyright 2016-2019 NXP
4  * All rights reserved.
5  *
6  * SPDX-License-Identifier: BSD-3-Clause
7  */
8 
9 #include "fsl_dspi.h"
10 
11 /*******************************************************************************
12  * Definitions
13  ******************************************************************************/
14 
15 /* Component ID definition, used by tools. */
16 #ifndef FSL_COMPONENT_ID
17 #define FSL_COMPONENT_ID "platform.drivers.dspi"
18 #endif
19 
20 /*! @brief Typedef for master interrupt handler. */
21 typedef void (*dspi_master_isr_t)(SPI_Type *base, dspi_master_handle_t *handle);
22 
23 /*! @brief Typedef for slave interrupt handler. */
24 typedef void (*dspi_slave_isr_t)(SPI_Type *base, dspi_slave_handle_t *handle);
25 
26 /*******************************************************************************
27  * Prototypes
28  ******************************************************************************/
29 /*!
30  * @brief Configures the DSPI peripheral chip select polarity.
31  *
32  * This function  takes in the desired peripheral chip select (Pcs) and it's corresponding desired polarity and
33  * configures the Pcs signal to operate with the desired characteristic.
34  *
35  * @param base DSPI peripheral address.
36  * @param pcs The particular peripheral chip select (parameter value is of type dspi_which_pcs_t) for which we wish to
37  *            apply the active high or active low characteristic.
38  * @param activeLowOrHigh The setting for either "active high, inactive low (0)"  or "active low, inactive high(1)" of
39  *                        type dspi_pcs_polarity_config_t.
40  */
41 static void DSPI_SetOnePcsPolarity(SPI_Type *base, dspi_which_pcs_t pcs, dspi_pcs_polarity_config_t activeLowOrHigh);
42 
43 /*!
44  * @brief Master fill up the TX FIFO with data.
45  * This is not a public API.
46  */
47 static void DSPI_MasterTransferFillUpTxFifo(SPI_Type *base, dspi_master_handle_t *handle);
48 
49 /*!
50  * @brief Master finish up a transfer.
51  * It would call back if there is callback function and set the state to idle.
52  * This is not a public API.
53  */
54 static void DSPI_MasterTransferComplete(SPI_Type *base, dspi_master_handle_t *handle);
55 
56 /*!
57  * @brief Slave fill up the TX FIFO with data.
58  * This is not a public API.
59  */
60 static void DSPI_SlaveTransferFillUpTxFifo(SPI_Type *base, dspi_slave_handle_t *handle);
61 
62 /*!
63  * @brief Slave finish up a transfer.
64  * It would call back if there is callback function and set the state to idle.
65  * This is not a public API.
66  */
67 static void DSPI_SlaveTransferComplete(SPI_Type *base, dspi_slave_handle_t *handle);
68 
69 /*!
70  * @brief DSPI common interrupt handler.
71  *
72  * @param base DSPI peripheral address.
73  * @param handle pointer to g_dspiHandle which stores the transfer state.
74  */
75 static void DSPI_CommonIRQHandler(SPI_Type *base, void *param);
76 
77 /*!
78  * @brief Master prepare the transfer.
79  * Basically it set up dspi_master_handle .
80  * This is not a public API.
81  */
82 static void DSPI_MasterTransferPrepare(SPI_Type *base, dspi_master_handle_t *handle, dspi_transfer_t *transfer);
83 
84 /*******************************************************************************
85  * Variables
86  ******************************************************************************/
87 
88 /* Defines constant value arrays for the baud rate pre-scalar and scalar divider values.*/
89 static const uint32_t s_baudratePrescaler[] = {2, 3, 5, 7};
90 static const uint32_t s_baudrateScaler[]    = {2,   4,   6,    8,    16,   32,   64,    128,
91                                             256, 512, 1024, 2048, 4096, 8192, 16384, 32768};
92 
93 static const uint32_t s_delayPrescaler[] = {1, 3, 5, 7};
94 static const uint32_t s_delayScaler[]    = {2,   4,    8,    16,   32,   64,    128,   256,
95                                          512, 1024, 2048, 4096, 8192, 16384, 32768, 65536};
96 
97 /*! @brief Pointers to dspi bases for each instance. */
98 static SPI_Type *const s_dspiBases[] = SPI_BASE_PTRS;
99 
100 /*! @brief Pointers to dspi IRQ number for each instance. */
101 static IRQn_Type const s_dspiIRQ[] = SPI_IRQS;
102 
103 #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
104 /*! @brief Pointers to dspi clocks for each instance. */
105 static clock_ip_name_t const s_dspiClock[] = DSPI_CLOCKS;
106 #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
107 
108 /*! @brief Pointers to dspi handles for each instance. */
109 static void *g_dspiHandle[ARRAY_SIZE(s_dspiBases)];
110 
111 /*! @brief Pointer to master IRQ handler for each instance. */
112 static dspi_master_isr_t s_dspiMasterIsr;
113 
114 /*! @brief Pointer to slave IRQ handler for each instance. */
115 static dspi_slave_isr_t s_dspiSlaveIsr;
116 
117 /* @brief Dummy data for each instance. This data is used when user's tx buffer is NULL*/
118 volatile uint8_t g_dspiDummyData[ARRAY_SIZE(s_dspiBases)] = {0};
119 /**********************************************************************************************************************
120  * Code
121  *********************************************************************************************************************/
122 /*!
123  * brief Get instance number for DSPI module.
124  *
125  * param base DSPI peripheral base address.
126  */
DSPI_GetInstance(SPI_Type * base)127 uint32_t DSPI_GetInstance(SPI_Type *base)
128 {
129     uint32_t instance;
130 
131     /* Find the instance index from base address mappings. */
132     for (instance = 0; instance < ARRAY_SIZE(s_dspiBases); instance++)
133     {
134         if (s_dspiBases[instance] == base)
135         {
136             break;
137         }
138     }
139 
140     assert(instance < ARRAY_SIZE(s_dspiBases));
141 
142     return instance;
143 }
144 
145 /*!
146  * brief Dummy data for each instance.
147  *
148  * The purpose of this API is to avoid MISRA rule8.5 : Multiple declarations of
149  * externally-linked object or function g_dspiDummyData.
150  *
151  * param base DSPI peripheral base address.
152  */
DSPI_GetDummyDataInstance(SPI_Type * base)153 uint8_t DSPI_GetDummyDataInstance(SPI_Type *base)
154 {
155     uint8_t instance = g_dspiDummyData[DSPI_GetInstance(base)];
156 
157     return instance;
158 }
159 
160 /*!
161  * brief Set up the dummy data.
162  *
163  * param base DSPI peripheral address.
164  * param dummyData Data to be transferred when tx buffer is NULL.
165  */
DSPI_SetDummyData(SPI_Type * base,uint8_t dummyData)166 void DSPI_SetDummyData(SPI_Type *base, uint8_t dummyData)
167 {
168     uint32_t instance         = DSPI_GetInstance(base);
169     g_dspiDummyData[instance] = dummyData;
170 }
171 
172 /*!
173  * brief Initializes the DSPI master.
174  *
175  * This function initializes the DSPI master configuration. This is an example use case.
176  *  code
177  *   dspi_master_config_t  masterConfig;
178  *   masterConfig.whichCtar                                = kDSPI_Ctar0;
179  *   masterConfig.ctarConfig.baudRate                      = 500000000U;
180  *   masterConfig.ctarConfig.bitsPerFrame                  = 8;
181  *   masterConfig.ctarConfig.cpol                          = kDSPI_ClockPolarityActiveHigh;
182  *   masterConfig.ctarConfig.cpha                          = kDSPI_ClockPhaseFirstEdge;
183  *   masterConfig.ctarConfig.direction                     = kDSPI_MsbFirst;
184  *   masterConfig.ctarConfig.pcsToSckDelayInNanoSec        = 1000000000U / masterConfig.ctarConfig.baudRate ;
185  *   masterConfig.ctarConfig.lastSckToPcsDelayInNanoSec    = 1000000000U / masterConfig.ctarConfig.baudRate ;
186  *   masterConfig.ctarConfig.betweenTransferDelayInNanoSec = 1000000000U / masterConfig.ctarConfig.baudRate ;
187  *   masterConfig.whichPcs                                 = kDSPI_Pcs0;
188  *   masterConfig.pcsActiveHighOrLow                       = kDSPI_PcsActiveLow;
189  *   masterConfig.enableContinuousSCK                      = false;
190  *   masterConfig.enableRxFifoOverWrite                    = false;
191  *   masterConfig.enableModifiedTimingFormat               = false;
192  *   masterConfig.samplePoint                              = kDSPI_SckToSin0Clock;
193  *   DSPI_MasterInit(base, &masterConfig, srcClock_Hz);
194  *  endcode
195  *
196  * param base DSPI peripheral address.
197  * param masterConfig Pointer to the structure dspi_master_config_t.
198  * param srcClock_Hz Module source input clock in Hertz.
199  */
DSPI_MasterInit(SPI_Type * base,const dspi_master_config_t * masterConfig,uint32_t srcClock_Hz)200 void DSPI_MasterInit(SPI_Type *base, const dspi_master_config_t *masterConfig, uint32_t srcClock_Hz)
201 {
202     assert(NULL != masterConfig);
203 
204     uint32_t temp;
205 #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
206     /* enable DSPI clock */
207     CLOCK_EnableClock(s_dspiClock[DSPI_GetInstance(base)]);
208 #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
209 
210     DSPI_Enable(base, true);
211     DSPI_StopTransfer(base);
212 
213     DSPI_SetOnePcsPolarity(base, masterConfig->whichPcs, masterConfig->pcsActiveHighOrLow);
214     DSPI_SetMasterSlaveMode(base, kDSPI_Master);
215 
216     temp = base->MCR & (~(SPI_MCR_CONT_SCKE_MASK | SPI_MCR_MTFE_MASK | SPI_MCR_ROOE_MASK | SPI_MCR_SMPL_PT_MASK |
217                           SPI_MCR_DIS_TXF_MASK | SPI_MCR_DIS_RXF_MASK));
218 
219     base->MCR = temp | SPI_MCR_CONT_SCKE(masterConfig->enableContinuousSCK) |
220                 SPI_MCR_MTFE(masterConfig->enableModifiedTimingFormat) |
221                 SPI_MCR_ROOE(masterConfig->enableRxFifoOverWrite) | SPI_MCR_SMPL_PT(masterConfig->samplePoint) |
222                 SPI_MCR_DIS_TXF(0U) | SPI_MCR_DIS_RXF(0U);
223 
224     if (0U == DSPI_MasterSetBaudRate(base, masterConfig->whichCtar, masterConfig->ctarConfig.baudRate, srcClock_Hz))
225     {
226         assert(false);
227     }
228 
229     temp = base->CTAR[masterConfig->whichCtar] &
230            ~(SPI_CTAR_FMSZ_MASK | SPI_CTAR_CPOL_MASK | SPI_CTAR_CPHA_MASK | SPI_CTAR_LSBFE_MASK);
231 
232     base->CTAR[masterConfig->whichCtar] = temp | SPI_CTAR_FMSZ(masterConfig->ctarConfig.bitsPerFrame - 1U) |
233                                           SPI_CTAR_CPOL(masterConfig->ctarConfig.cpol) |
234                                           SPI_CTAR_CPHA(masterConfig->ctarConfig.cpha) |
235                                           SPI_CTAR_LSBFE(masterConfig->ctarConfig.direction);
236 
237     (void)DSPI_MasterSetDelayTimes(base, masterConfig->whichCtar, kDSPI_PcsToSck, srcClock_Hz,
238                                    masterConfig->ctarConfig.pcsToSckDelayInNanoSec);
239     (void)DSPI_MasterSetDelayTimes(base, masterConfig->whichCtar, kDSPI_LastSckToPcs, srcClock_Hz,
240                                    masterConfig->ctarConfig.lastSckToPcsDelayInNanoSec);
241     (void)DSPI_MasterSetDelayTimes(base, masterConfig->whichCtar, kDSPI_BetweenTransfer, srcClock_Hz,
242                                    masterConfig->ctarConfig.betweenTransferDelayInNanoSec);
243 
244     DSPI_SetDummyData(base, DSPI_DUMMY_DATA);
245     DSPI_StartTransfer(base);
246 }
247 
248 /*!
249  * brief Sets the dspi_master_config_t structure to default values.
250  *
251  * The purpose of this API is to get the configuration structure initialized for the DSPI_MasterInit().
252  * Users may use the initialized structure unchanged in the DSPI_MasterInit() or modify the structure
253  * before calling the DSPI_MasterInit().
254  * Example:
255  * code
256  *  dspi_master_config_t  masterConfig;
257  *  DSPI_MasterGetDefaultConfig(&masterConfig);
258  * endcode
259  * param masterConfig pointer to dspi_master_config_t structure
260  */
DSPI_MasterGetDefaultConfig(dspi_master_config_t * masterConfig)261 void DSPI_MasterGetDefaultConfig(dspi_master_config_t *masterConfig)
262 {
263     assert(NULL != masterConfig);
264 
265     /* Initializes the configure structure to zero. */
266     (void)memset(masterConfig, 0, sizeof(*masterConfig));
267 
268     masterConfig->whichCtar               = kDSPI_Ctar0;
269     masterConfig->ctarConfig.baudRate     = 500000;
270     masterConfig->ctarConfig.bitsPerFrame = 8;
271     masterConfig->ctarConfig.cpol         = kDSPI_ClockPolarityActiveHigh;
272     masterConfig->ctarConfig.cpha         = kDSPI_ClockPhaseFirstEdge;
273     masterConfig->ctarConfig.direction    = kDSPI_MsbFirst;
274 
275     masterConfig->ctarConfig.pcsToSckDelayInNanoSec        = 1000;
276     masterConfig->ctarConfig.lastSckToPcsDelayInNanoSec    = 1000;
277     masterConfig->ctarConfig.betweenTransferDelayInNanoSec = 1000;
278 
279     masterConfig->whichPcs           = kDSPI_Pcs0;
280     masterConfig->pcsActiveHighOrLow = kDSPI_PcsActiveLow;
281 
282     masterConfig->enableContinuousSCK        = false;
283     masterConfig->enableRxFifoOverWrite      = false;
284     masterConfig->enableModifiedTimingFormat = false;
285     masterConfig->samplePoint                = kDSPI_SckToSin0Clock;
286 }
287 
288 /*!
289  * brief DSPI slave configuration.
290  *
291  * This function initializes the DSPI slave configuration. This is an example use case.
292  *  code
293  *   dspi_slave_config_t  slaveConfig;
294  *  slaveConfig->whichCtar                  = kDSPI_Ctar0;
295  *  slaveConfig->ctarConfig.bitsPerFrame    = 8;
296  *  slaveConfig->ctarConfig.cpol            = kDSPI_ClockPolarityActiveHigh;
297  *  slaveConfig->ctarConfig.cpha            = kDSPI_ClockPhaseFirstEdge;
298  *  slaveConfig->enableContinuousSCK        = false;
299  *  slaveConfig->enableRxFifoOverWrite      = false;
300  *  slaveConfig->enableModifiedTimingFormat = false;
301  *  slaveConfig->samplePoint                = kDSPI_SckToSin0Clock;
302  *   DSPI_SlaveInit(base, &slaveConfig);
303  *  endcode
304  *
305  * param base DSPI peripheral address.
306  * param slaveConfig Pointer to the structure dspi_master_config_t.
307  */
DSPI_SlaveInit(SPI_Type * base,const dspi_slave_config_t * slaveConfig)308 void DSPI_SlaveInit(SPI_Type *base, const dspi_slave_config_t *slaveConfig)
309 {
310     assert(NULL != slaveConfig);
311 
312     uint32_t temp = 0;
313 
314 #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
315     /* enable DSPI clock */
316     CLOCK_EnableClock(s_dspiClock[DSPI_GetInstance(base)]);
317 #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
318 
319     DSPI_Enable(base, true);
320     DSPI_StopTransfer(base);
321 
322     DSPI_SetMasterSlaveMode(base, kDSPI_Slave);
323 
324     temp = base->MCR & (~(SPI_MCR_CONT_SCKE_MASK | SPI_MCR_MTFE_MASK | SPI_MCR_ROOE_MASK | SPI_MCR_SMPL_PT_MASK |
325                           SPI_MCR_DIS_TXF_MASK | SPI_MCR_DIS_RXF_MASK));
326 
327     base->MCR = temp | SPI_MCR_CONT_SCKE(slaveConfig->enableContinuousSCK) |
328                 SPI_MCR_MTFE(slaveConfig->enableModifiedTimingFormat) |
329                 SPI_MCR_ROOE(slaveConfig->enableRxFifoOverWrite) | SPI_MCR_SMPL_PT(slaveConfig->samplePoint) |
330                 SPI_MCR_DIS_TXF(0U) | SPI_MCR_DIS_RXF(0U);
331 
332     DSPI_SetOnePcsPolarity(base, kDSPI_Pcs0, kDSPI_PcsActiveLow);
333 
334     temp = base->CTAR[slaveConfig->whichCtar] &
335            ~(SPI_CTAR_FMSZ_MASK | SPI_CTAR_CPOL_MASK | SPI_CTAR_CPHA_MASK | SPI_CTAR_LSBFE_MASK);
336 
337     base->CTAR[slaveConfig->whichCtar] = temp | SPI_CTAR_SLAVE_FMSZ(slaveConfig->ctarConfig.bitsPerFrame - 1U) |
338                                          SPI_CTAR_SLAVE_CPOL(slaveConfig->ctarConfig.cpol) |
339                                          SPI_CTAR_SLAVE_CPHA(slaveConfig->ctarConfig.cpha);
340 
341     DSPI_SetDummyData(base, DSPI_DUMMY_DATA);
342 
343     DSPI_StartTransfer(base);
344 }
345 
346 /*!
347  * brief Sets the dspi_slave_config_t structure to a default value.
348  *
349  * The purpose of this API is to get the configuration structure initialized for the DSPI_SlaveInit().
350  * Users may use the initialized structure unchanged in the DSPI_SlaveInit() or modify the structure
351  * before calling the DSPI_SlaveInit().
352  * This is an example.
353  * code
354  *  dspi_slave_config_t  slaveConfig;
355  *  DSPI_SlaveGetDefaultConfig(&slaveConfig);
356  * endcode
357  * param slaveConfig Pointer to the dspi_slave_config_t structure.
358  */
DSPI_SlaveGetDefaultConfig(dspi_slave_config_t * slaveConfig)359 void DSPI_SlaveGetDefaultConfig(dspi_slave_config_t *slaveConfig)
360 {
361     assert(NULL != slaveConfig);
362 
363     /* Initializes the configure structure to zero. */
364     (void)memset(slaveConfig, 0, sizeof(*slaveConfig));
365 
366     slaveConfig->whichCtar               = kDSPI_Ctar0;
367     slaveConfig->ctarConfig.bitsPerFrame = 8;
368     slaveConfig->ctarConfig.cpol         = kDSPI_ClockPolarityActiveHigh;
369     slaveConfig->ctarConfig.cpha         = kDSPI_ClockPhaseFirstEdge;
370 
371     slaveConfig->enableContinuousSCK        = false;
372     slaveConfig->enableRxFifoOverWrite      = false;
373     slaveConfig->enableModifiedTimingFormat = false;
374     slaveConfig->samplePoint                = kDSPI_SckToSin0Clock;
375 }
376 
377 /*!
378  * brief De-initializes the DSPI peripheral. Call this API to disable the DSPI clock.
379  * param base DSPI peripheral address.
380  */
DSPI_Deinit(SPI_Type * base)381 void DSPI_Deinit(SPI_Type *base)
382 {
383     DSPI_StopTransfer(base);
384     DSPI_Enable(base, false);
385 
386 #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
387     /* disable DSPI clock */
388     CLOCK_DisableClock(s_dspiClock[DSPI_GetInstance(base)]);
389 #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
390 }
391 
DSPI_SetOnePcsPolarity(SPI_Type * base,dspi_which_pcs_t pcs,dspi_pcs_polarity_config_t activeLowOrHigh)392 static void DSPI_SetOnePcsPolarity(SPI_Type *base, dspi_which_pcs_t pcs, dspi_pcs_polarity_config_t activeLowOrHigh)
393 {
394     uint32_t temp;
395 
396     temp = base->MCR;
397 
398     if (activeLowOrHigh == kDSPI_PcsActiveLow)
399     {
400         temp |= SPI_MCR_PCSIS(pcs);
401     }
402     else
403     {
404         temp &= ~SPI_MCR_PCSIS(pcs);
405     }
406 
407     base->MCR = temp;
408 }
409 
410 /*!
411  * brief Sets the DSPI baud rate in bits per second.
412  *
413  * This function  takes in the desired baudRate_Bps (baud rate) and calculates the nearest possible baud rate without
414  * exceeding the desired baud rate, and returns the calculated baud rate in bits-per-second. It requires that the
415  * caller also provide the frequency of the module source clock (in Hertz).
416  *
417  * param base DSPI peripheral address.
418  * param whichCtar The desired Clock and Transfer Attributes Register (CTAR) of the type dspi_ctar_selection_t
419  * param baudRate_Bps The desired baud rate in bits per second
420  * param srcClock_Hz Module source input clock in Hertz
421  * return The actual calculated baud rate
422  */
DSPI_MasterSetBaudRate(SPI_Type * base,dspi_ctar_selection_t whichCtar,uint32_t baudRate_Bps,uint32_t srcClock_Hz)423 uint32_t DSPI_MasterSetBaudRate(SPI_Type *base,
424                                 dspi_ctar_selection_t whichCtar,
425                                 uint32_t baudRate_Bps,
426                                 uint32_t srcClock_Hz)
427 {
428     /* for master mode configuration, if slave mode detected, return 0*/
429     if (!DSPI_IsMaster(base))
430     {
431         return 0U;
432     }
433     uint32_t temp;
434     uint32_t prescaler, bestPrescaler;
435     uint32_t scaler, bestScaler;
436     uint32_t dbr, bestDbr;
437     uint32_t realBaudrate, bestBaudrate;
438     uint32_t diff, min_diff;
439     uint32_t baudrate = baudRate_Bps;
440 
441     /* find combination of prescaler and scaler resulting in baudrate closest to the requested value */
442     min_diff      = 0xFFFFFFFFU;
443     bestPrescaler = 0;
444     bestScaler    = 0;
445     bestDbr       = 1;
446     bestBaudrate  = 0; /* required to avoid compilation warning */
447 
448     /* In all for loops, if min_diff = 0, the exit for loop*/
449     for (prescaler = 0U; prescaler < 4U; prescaler++)
450     {
451         for (scaler = 0U; scaler < 16U; scaler++)
452         {
453             for (dbr = 1U; dbr < 3U; dbr++)
454             {
455                 realBaudrate = ((srcClock_Hz * dbr) / (s_baudratePrescaler[prescaler] * (s_baudrateScaler[scaler])));
456 
457                 /* calculate the baud rate difference based on the conditional statement that states that the calculated
458                  * baud rate must not exceed the desired baud rate.
459                  */
460                 if (baudrate >= realBaudrate)
461                 {
462                     diff = baudrate - realBaudrate;
463                     if (min_diff > diff)
464                     {
465                         /* a better match found */
466                         min_diff      = diff;
467                         bestPrescaler = prescaler;
468                         bestScaler    = scaler;
469                         bestBaudrate  = realBaudrate;
470                         bestDbr       = dbr;
471                     }
472                 }
473                 if (0U == min_diff)
474                 {
475                     break;
476                 }
477             }
478 
479             if (0U == min_diff)
480             {
481                 break;
482             }
483         }
484         if (0U == min_diff)
485         {
486             break;
487         }
488     }
489 
490     /* write the best dbr, prescalar, and baud rate scalar to the CTAR */
491     temp = base->CTAR[whichCtar] & ~(SPI_CTAR_DBR_MASK | SPI_CTAR_PBR_MASK | SPI_CTAR_BR_MASK);
492 
493     base->CTAR[whichCtar] = temp | ((bestDbr - 1U) << SPI_CTAR_DBR_SHIFT) | (bestPrescaler << SPI_CTAR_PBR_SHIFT) |
494                             (bestScaler << SPI_CTAR_BR_SHIFT);
495 
496     /* return the actual calculated baud rate */
497     return bestBaudrate;
498 }
499 
500 /*!
501  * brief Manually configures the delay prescaler and scaler for a particular CTAR.
502  *
503  * This function configures the PCS to SCK delay pre-scalar (PcsSCK) and scalar (CSSCK), after SCK delay pre-scalar
504  * (PASC) and scalar (ASC), and the delay after transfer pre-scalar (PDT) and scalar (DT).
505  *
506  * These delay names are available in the type dspi_delay_type_t.
507  *
508  * The user passes the delay to the configuration along with the prescaler and scaler value.
509  * This allows the user to directly set the prescaler/scaler values if pre-calculated or
510  * to manually increment either value.
511  *
512  * param base DSPI peripheral address.
513  * param whichCtar The desired Clock and Transfer Attributes Register (CTAR) of type dspi_ctar_selection_t.
514  * param prescaler The prescaler delay value (can be an integer 0, 1, 2, or 3).
515  * param scaler The scaler delay value (can be any integer between 0 to 15).
516  * param whichDelay The desired delay to configure; must be of type dspi_delay_type_t
517  */
DSPI_MasterSetDelayScaler(SPI_Type * base,dspi_ctar_selection_t whichCtar,uint32_t prescaler,uint32_t scaler,dspi_delay_type_t whichDelay)518 void DSPI_MasterSetDelayScaler(
519     SPI_Type *base, dspi_ctar_selection_t whichCtar, uint32_t prescaler, uint32_t scaler, dspi_delay_type_t whichDelay)
520 {
521     /* these settings are only relevant in master mode */
522     if (DSPI_IsMaster(base))
523     {
524         switch (whichDelay)
525         {
526             case kDSPI_PcsToSck:
527                 base->CTAR[whichCtar] = (base->CTAR[whichCtar] & (~SPI_CTAR_PCSSCK_MASK) & (~SPI_CTAR_CSSCK_MASK)) |
528                                         SPI_CTAR_PCSSCK(prescaler) | SPI_CTAR_CSSCK(scaler);
529                 break;
530             case kDSPI_LastSckToPcs:
531                 base->CTAR[whichCtar] = (base->CTAR[whichCtar] & (~SPI_CTAR_PASC_MASK) & (~SPI_CTAR_ASC_MASK)) |
532                                         SPI_CTAR_PASC(prescaler) | SPI_CTAR_ASC(scaler);
533                 break;
534             case kDSPI_BetweenTransfer:
535                 base->CTAR[whichCtar] = (base->CTAR[whichCtar] & (~SPI_CTAR_PDT_MASK) & (~SPI_CTAR_DT_MASK)) |
536                                         SPI_CTAR_PDT(prescaler) | SPI_CTAR_DT(scaler);
537                 break;
538             default:
539                 /* All cases have been listed above, the default clause should not be reached. */
540                 assert(false);
541                 break;
542         }
543     }
544 }
545 
546 /*!
547  * brief Calculates the delay prescaler and scaler based on the desired delay input in nanoseconds.
548  *
549  * This function calculates the values for the following.
550  * PCS to SCK delay pre-scalar (PCSSCK) and scalar (CSSCK), or
551  * After SCK delay pre-scalar (PASC) and scalar (ASC), or
552  * Delay after transfer pre-scalar (PDT) and scalar (DT).
553  *
554  * These delay names are available in the type dspi_delay_type_t.
555  *
556  * The user passes which delay to configure along with the desired delay value in nanoseconds.  The function
557  * calculates the values needed for the prescaler and scaler. Note that returning the calculated delay as an exact
558  * delay match may not be possible. In this case, the closest match is calculated without going below the desired
559  * delay value input.
560  * It is possible to input a very large delay value that exceeds the capability of the part, in which case the maximum
561  * supported delay is returned. The higher-level peripheral driver alerts the user of an out of range delay
562  * input.
563  *
564  * param base DSPI peripheral address.
565  * param whichCtar The desired Clock and Transfer Attributes Register (CTAR) of type dspi_ctar_selection_t.
566  * param whichDelay The desired delay to configure, must be of type dspi_delay_type_t
567  * param srcClock_Hz Module source input clock in Hertz
568  * param delayTimeInNanoSec The desired delay value in nanoseconds.
569  * return The actual calculated delay value.
570  */
DSPI_MasterSetDelayTimes(SPI_Type * base,dspi_ctar_selection_t whichCtar,dspi_delay_type_t whichDelay,uint32_t srcClock_Hz,uint32_t delayTimeInNanoSec)571 uint32_t DSPI_MasterSetDelayTimes(SPI_Type *base,
572                                   dspi_ctar_selection_t whichCtar,
573                                   dspi_delay_type_t whichDelay,
574                                   uint32_t srcClock_Hz,
575                                   uint32_t delayTimeInNanoSec)
576 {
577     /* for master mode configuration, if slave mode detected, return 0 */
578     if (!DSPI_IsMaster(base))
579     {
580         return 0U;
581     }
582 
583     uint32_t prescaler, bestPrescaler;
584     uint32_t scaler, bestScaler;
585     uint32_t realDelay, bestDelay;
586     uint32_t diff, min_diff;
587     uint32_t initialDelayNanoSec;
588 
589     /* find combination of prescaler and scaler resulting in the delay closest to the
590      * requested value
591      */
592     min_diff = 0xFFFFFFFFU;
593     /* Initialize prescaler and scaler to their max values to generate the max delay */
594     bestPrescaler = 0x3;
595     bestScaler    = 0xF;
596     bestDelay = (((1000000000U * 4U) / srcClock_Hz) * s_delayPrescaler[bestPrescaler] * s_delayScaler[bestScaler]) / 4U;
597 
598     /* First calculate the initial, default delay */
599     initialDelayNanoSec = 1000000000U / srcClock_Hz * 2U;
600 
601     /* If the initial, default delay is already greater than the desired delay, then
602      * set the delays to their initial value (0) and return the delay. In other words,
603      * there is no way to decrease the delay value further.
604      */
605     if (initialDelayNanoSec >= delayTimeInNanoSec)
606     {
607         DSPI_MasterSetDelayScaler(base, whichCtar, 0, 0, whichDelay);
608         return initialDelayNanoSec;
609     }
610 
611     /* In all for loops, if min_diff = 0, the exit for loop */
612     for (prescaler = 0; prescaler < 4U; prescaler++)
613     {
614         for (scaler = 0; scaler < 16U; scaler++)
615         {
616             realDelay = ((4000000000U / srcClock_Hz) * s_delayPrescaler[prescaler] * s_delayScaler[scaler]) / 4U;
617 
618             /* calculate the delay difference based on the conditional statement
619              * that states that the calculated delay must not be less then the desired delay
620              */
621             if (realDelay >= delayTimeInNanoSec)
622             {
623                 diff = realDelay - delayTimeInNanoSec;
624                 if (min_diff > diff)
625                 {
626                     /* a better match found */
627                     min_diff      = diff;
628                     bestPrescaler = prescaler;
629                     bestScaler    = scaler;
630                     bestDelay     = realDelay;
631                 }
632             }
633 
634             if (0U == min_diff)
635             {
636                 break;
637             }
638         }
639         if (0U == min_diff)
640         {
641             break;
642         }
643     }
644 
645     /* write the best dbr, prescalar, and baud rate scalar to the CTAR */
646     DSPI_MasterSetDelayScaler(base, whichCtar, bestPrescaler, bestScaler, whichDelay);
647 
648     /* return the actual calculated baud rate */
649     return bestDelay;
650 }
651 
652 /*!
653  * brief Sets the dspi_command_data_config_t structure to default values.
654  *
655  * The purpose of this API is to get the configuration structure initialized for use in the DSPI_MasterWrite_xx().
656  * Users may use the initialized structure unchanged in the DSPI_MasterWrite_xx() or modify the structure
657  * before calling the DSPI_MasterWrite_xx().
658  * This is an example.
659  * code
660  *  dspi_command_data_config_t  command;
661  *  DSPI_GetDefaultDataCommandConfig(&command);
662  * endcode
663  * param command Pointer to the dspi_command_data_config_t structure.
664  */
DSPI_GetDefaultDataCommandConfig(dspi_command_data_config_t * command)665 void DSPI_GetDefaultDataCommandConfig(dspi_command_data_config_t *command)
666 {
667     assert(NULL != command);
668 
669     /* Initializes the configure structure to zero. */
670     (void)memset(command, 0, sizeof(*command));
671 
672     command->isPcsContinuous    = false;
673     command->whichCtar          = (uint8_t)kDSPI_Ctar0;
674     command->whichPcs           = (uint8_t)kDSPI_Pcs0;
675     command->isEndOfQueue       = false;
676     command->clearTransferCount = false;
677 }
678 
679 /*!
680  * brief Writes data into the data buffer master mode and waits till complete to return.
681  *
682  * In master mode, the 16-bit data is appended to the 16-bit command info. The command portion
683  * provides characteristics of the data, such as the optional continuous chip select
684  * operation between transfers, the desired Clock and Transfer Attributes register to use for the
685  * associated SPI frame, the desired PCS signal to use for the data transfer, whether the current
686  * transfer is the last in the queue, and whether to clear the transfer count (normally needed when
687  * sending the first frame of a data packet). This is an example.
688  * code
689  *  dspi_command_config_t commandConfig;
690  *  commandConfig.isPcsContinuous = true;
691  *  commandConfig.whichCtar = kDSPICtar0;
692  *  commandConfig.whichPcs = kDSPIPcs1;
693  *  commandConfig.clearTransferCount = false;
694  *  commandConfig.isEndOfQueue = false;
695  *  DSPI_MasterWriteDataBlocking(base, &commandConfig, dataWord);
696  * endcode
697  *
698  * Note that this function does not return until after the transmit is complete. Also note that the DSPI must be
699  * enabled and running to transmit data (MCR[MDIS] & [HALT] = 0). Because the SPI is a synchronous protocol,
700  * the received data is available when the transmit completes.
701  *
702  * param base DSPI peripheral address.
703  * param command Pointer to the command structure.
704  * param data The data word to be sent.
705  */
DSPI_MasterWriteDataBlocking(SPI_Type * base,dspi_command_data_config_t * command,uint16_t data)706 void DSPI_MasterWriteDataBlocking(SPI_Type *base, dspi_command_data_config_t *command, uint16_t data)
707 {
708     assert(NULL != command);
709 
710     /* First, clear Transmit Complete Flag (TCF) */
711     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxCompleteFlag);
712 
713     while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
714     {
715         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
716     }
717 
718     base->PUSHR = SPI_PUSHR_CONT(command->isPcsContinuous) | SPI_PUSHR_CTAS(command->whichCtar) |
719                   SPI_PUSHR_PCS(command->whichPcs) | SPI_PUSHR_EOQ(command->isEndOfQueue) |
720                   SPI_PUSHR_CTCNT(command->clearTransferCount) | SPI_PUSHR_TXDATA(data);
721     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
722 
723     /* Wait till TCF sets */
724     while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxCompleteFlag))
725     {
726     }
727 }
728 
729 /*!
730  * brief Writes a 32-bit data word (16-bit command appended with 16-bit data) into the data
731  *        buffer master mode and waits till complete to return.
732  *
733  * In this function, the user must append the 16-bit data to the 16-bit command information and then provide the total
734  * 32-bit word
735  * as the data to send.
736  * The command portion provides characteristics of the data, such as the optional continuous chip select operation
737  * between transfers, the desired Clock and Transfer Attributes register to use for the associated SPI frame, the
738  * desired PCS
739  * signal to use for the data transfer, whether the current transfer is the last in the queue, and whether to clear the
740  * transfer count (normally needed when sending the first frame of a data packet). The user is responsible for
741  * appending this command with the data to send. This is an example:
742  * code
743  *  dataWord = <16-bit command> | <16-bit data>;
744  *  DSPI_MasterWriteCommandDataBlocking(base, dataWord);
745  * endcode
746  *
747  * Note that this function does not return until after the transmit is complete. Also note that the DSPI must be
748  * enabled and running to transmit data (MCR[MDIS] & [HALT] = 0).
749  * Because the SPI is a synchronous protocol, the received data is available when the transmit completes.
750  *
751  *  For a blocking polling transfer, see methods below.
752  *  Option 1:
753  *   uint32_t command_to_send = DSPI_MasterGetFormattedCommand(&command);
754  *   uint32_t data0 = command_to_send | data_need_to_send_0;
755  *   uint32_t data1 = command_to_send | data_need_to_send_1;
756  *   uint32_t data2 = command_to_send | data_need_to_send_2;
757  *
758  *   DSPI_MasterWriteCommandDataBlocking(base,data0);
759  *   DSPI_MasterWriteCommandDataBlocking(base,data1);
760  *   DSPI_MasterWriteCommandDataBlocking(base,data2);
761  *
762  *  Option 2:
763  *   DSPI_MasterWriteDataBlocking(base,&command,data_need_to_send_0);
764  *   DSPI_MasterWriteDataBlocking(base,&command,data_need_to_send_1);
765  *   DSPI_MasterWriteDataBlocking(base,&command,data_need_to_send_2);
766  *
767  * param base DSPI peripheral address.
768  * param data The data word (command and data combined) to be sent.
769  */
DSPI_MasterWriteCommandDataBlocking(SPI_Type * base,uint32_t data)770 void DSPI_MasterWriteCommandDataBlocking(SPI_Type *base, uint32_t data)
771 {
772     /* First, clear Transmit Complete Flag (TCF) */
773     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxCompleteFlag);
774 
775     while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
776     {
777         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
778     }
779 
780     base->PUSHR = data;
781 
782     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
783 
784     /* Wait till TCF sets */
785     while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxCompleteFlag))
786     {
787     }
788 }
789 
790 /*!
791  * brief Writes data into the data buffer in slave mode, waits till data was transmitted, and returns.
792  *
793  * In slave mode, up to 16-bit words may be written. The function first clears the transmit complete flag, writes data
794  * into data register, and finally waits until the data is transmitted.
795  *
796  * param base DSPI peripheral address.
797  * param data The data to send.
798  */
DSPI_SlaveWriteDataBlocking(SPI_Type * base,uint32_t data)799 void DSPI_SlaveWriteDataBlocking(SPI_Type *base, uint32_t data)
800 {
801     /* First, clear Transmit Complete Flag (TCF) */
802     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxCompleteFlag);
803 
804     while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
805     {
806         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
807     }
808 
809     base->PUSHR_SLAVE = data;
810 
811     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
812 
813     /* Wait till TCF sets */
814     while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxCompleteFlag))
815     {
816     }
817 }
818 
819 /*!
820  * brief Enables the DSPI interrupts.
821  *
822  * This function configures the various interrupt masks of the DSPI.  The parameters are a base and an interrupt mask.
823  * Note, for Tx Fill and Rx FIFO drain requests, enable the interrupt request and disable the DMA request.
824  *       Do not use this API(write to RSER register) while DSPI is in running state.
825  *
826  * code
827  *  DSPI_EnableInterrupts(base, kDSPI_TxCompleteInterruptEnable | kDSPI_EndOfQueueInterruptEnable );
828  * endcode
829  *
830  * param base DSPI peripheral address.
831  * param mask The interrupt mask; use the enum _dspi_interrupt_enable.
832  */
DSPI_EnableInterrupts(SPI_Type * base,uint32_t mask)833 void DSPI_EnableInterrupts(SPI_Type *base, uint32_t mask)
834 {
835     if (0U != (mask & SPI_RSER_TFFF_RE_MASK))
836     {
837         base->RSER &= ~SPI_RSER_TFFF_DIRS_MASK;
838     }
839     if (0U != (mask & SPI_RSER_RFDF_RE_MASK))
840     {
841         base->RSER &= ~SPI_RSER_RFDF_DIRS_MASK;
842     }
843     base->RSER |= mask;
844 }
845 
846 /*Transactional APIs -- Master*/
847 
848 /*!
849  * brief Initializes the DSPI master handle.
850  *
851  * This function initializes the DSPI handle, which can be used for other DSPI transactional APIs.  Usually, for a
852  * specified DSPI instance,  call this API once to get the initialized handle.
853  *
854  * param base DSPI peripheral base address.
855  * param handle DSPI handle pointer to dspi_master_handle_t.
856  * param callback DSPI callback.
857  * param userData Callback function parameter.
858  */
DSPI_MasterTransferCreateHandle(SPI_Type * base,dspi_master_handle_t * handle,dspi_master_transfer_callback_t callback,void * userData)859 void DSPI_MasterTransferCreateHandle(SPI_Type *base,
860                                      dspi_master_handle_t *handle,
861                                      dspi_master_transfer_callback_t callback,
862                                      void *userData)
863 {
864     assert(NULL != handle);
865 
866     /* Zero the handle. */
867     (void)memset(handle, 0, sizeof(*handle));
868 
869     g_dspiHandle[DSPI_GetInstance(base)] = handle;
870 
871     handle->callback = callback;
872     handle->userData = userData;
873 }
874 
875 /*!
876  * brief DSPI master transfer data using polling.
877  *
878  * This function transfers data using polling. This is a blocking function, which does not return until all transfers
879  * have been completed.
880  *
881  * param base DSPI peripheral base address.
882  * param transfer Pointer to the dspi_transfer_t structure.
883  * return status of status_t.
884  */
DSPI_MasterTransferBlocking(SPI_Type * base,dspi_transfer_t * transfer)885 status_t DSPI_MasterTransferBlocking(SPI_Type *base, dspi_transfer_t *transfer)
886 {
887     assert(NULL != transfer);
888 
889     uint16_t wordToSend   = 0;
890     uint16_t wordReceived = 0;
891     uint8_t dummyData     = DSPI_GetDummyDataInstance(base);
892     uint8_t bitsPerFrame;
893 
894     uint32_t command;
895     uint32_t lastCommand;
896 
897     const uint8_t *txData;
898     uint8_t *rxData;
899     uint32_t remainingSendByteCount;
900     uint32_t remainingReceiveByteCount;
901 
902     uint32_t fifoSize;
903     uint32_t tmpMCR = 0;
904     dspi_command_data_config_t commandStruct;
905 
906     /* If the transfer count is zero, then return immediately.*/
907     if (transfer->dataSize == 0U)
908     {
909         return kStatus_InvalidArgument;
910     }
911 
912     DSPI_StopTransfer(base);
913     DSPI_DisableInterrupts(base, (uint32_t)kDSPI_AllInterruptEnable);
914     DSPI_FlushFifo(base, true, true);
915     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_AllStatusFlag);
916 
917     /*Calculate the command and lastCommand*/
918     commandStruct.whichPcs =
919         (uint8_t)((uint32_t)1U << ((transfer->configFlags & DSPI_MASTER_PCS_MASK) >> DSPI_MASTER_PCS_SHIFT));
920     commandStruct.isEndOfQueue       = false;
921     commandStruct.clearTransferCount = false;
922     commandStruct.whichCtar = (uint8_t)((transfer->configFlags & DSPI_MASTER_CTAR_MASK) >> DSPI_MASTER_CTAR_SHIFT);
923     commandStruct.isPcsContinuous =
924         (0U != (transfer->configFlags & (uint32_t)kDSPI_MasterPcsContinuous)) ? true : false;
925 
926     command = DSPI_MasterGetFormattedCommand(&(commandStruct));
927 
928     commandStruct.isEndOfQueue = true;
929     commandStruct.isPcsContinuous =
930         (0U != (transfer->configFlags & (uint32_t)kDSPI_MasterActiveAfterTransfer)) ? true : false;
931     lastCommand = DSPI_MasterGetFormattedCommand(&(commandStruct));
932 
933     /*Calculate the bitsPerFrame*/
934     bitsPerFrame = (uint8_t)(((base->CTAR[commandStruct.whichCtar] & SPI_CTAR_FMSZ_MASK) >> SPI_CTAR_FMSZ_SHIFT) + 1U);
935 
936     txData                    = transfer->txData;
937     rxData                    = transfer->rxData;
938     remainingSendByteCount    = transfer->dataSize;
939     remainingReceiveByteCount = transfer->dataSize;
940 
941     tmpMCR = base->MCR;
942     if ((0U != (tmpMCR & SPI_MCR_DIS_RXF_MASK)) || (0U != (tmpMCR & SPI_MCR_DIS_TXF_MASK)))
943     {
944         fifoSize = 1U;
945     }
946     else
947     {
948         fifoSize = (uint32_t)FSL_FEATURE_DSPI_FIFO_SIZEn(base);
949     }
950 
951     DSPI_StartTransfer(base);
952 
953     if (bitsPerFrame <= 8U)
954     {
955         while (remainingSendByteCount > 0U)
956         {
957             if (remainingSendByteCount == 1U)
958             {
959                 while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
960                 {
961                     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
962                 }
963 
964                 if (txData != NULL)
965                 {
966                     base->PUSHR = (*txData) | (lastCommand);
967                     txData++;
968                 }
969                 else
970                 {
971                     base->PUSHR = (lastCommand) | (dummyData);
972                 }
973                 DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
974                 remainingSendByteCount--;
975 
976                 while (remainingReceiveByteCount > 0U)
977                 {
978                     if ((uint32_t)kDSPI_RxFifoDrainRequestFlag ==
979                         (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoDrainRequestFlag))
980                     {
981                         if (rxData != NULL)
982                         {
983                             /* Read data from POPR*/
984                             *(rxData) = (uint8_t)DSPI_ReadData(base);
985                             rxData++;
986                         }
987                         else
988                         {
989                             (void)DSPI_ReadData(base);
990                         }
991                         remainingReceiveByteCount--;
992 
993                         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoDrainRequestFlag);
994                     }
995                 }
996             }
997             else
998             {
999                 /*Wait until Tx Fifo is not full*/
1000                 while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
1001                 {
1002                     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1003                 }
1004                 if (txData != NULL)
1005                 {
1006                     base->PUSHR = command | (uint16_t)(*txData);
1007                     txData++;
1008                 }
1009                 else
1010                 {
1011                     base->PUSHR = command | dummyData;
1012                 }
1013                 remainingSendByteCount--;
1014 
1015                 DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1016 
1017                 while ((remainingReceiveByteCount - remainingSendByteCount) >= fifoSize)
1018                 {
1019                     if ((uint32_t)kDSPI_RxFifoDrainRequestFlag ==
1020                         (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoDrainRequestFlag))
1021                     {
1022                         if (rxData != NULL)
1023                         {
1024                             *(rxData) = (uint8_t)DSPI_ReadData(base);
1025                             rxData++;
1026                         }
1027                         else
1028                         {
1029                             (void)DSPI_ReadData(base);
1030                         }
1031                         remainingReceiveByteCount--;
1032 
1033                         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoDrainRequestFlag);
1034                     }
1035                 }
1036             }
1037         }
1038     }
1039     else
1040     {
1041         while (remainingSendByteCount > 0U)
1042         {
1043             if (remainingSendByteCount <= 2U)
1044             {
1045                 while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
1046                 {
1047                     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1048                 }
1049 
1050                 if (txData != NULL)
1051                 {
1052                     wordToSend = *(txData);
1053                     ++txData;
1054 
1055                     if (remainingSendByteCount > 1U)
1056                     {
1057                         wordToSend |= (uint16_t)(*(txData)) << 8U;
1058                         ++txData;
1059                     }
1060                 }
1061                 else
1062                 {
1063                     wordToSend = dummyData;
1064                 }
1065 
1066                 base->PUSHR = lastCommand | wordToSend;
1067 
1068                 DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1069                 remainingSendByteCount = 0;
1070 
1071                 while (remainingReceiveByteCount > 0U)
1072                 {
1073                     if ((uint32_t)kDSPI_RxFifoDrainRequestFlag ==
1074                         (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoDrainRequestFlag))
1075                     {
1076                         wordReceived = (uint16_t)DSPI_ReadData(base);
1077 
1078                         if (remainingReceiveByteCount != 1U)
1079                         {
1080                             if (rxData != NULL)
1081                             {
1082                                 *(rxData) = (uint8_t)wordReceived;
1083                                 ++rxData;
1084                                 *(rxData) = (uint8_t)(wordReceived >> 8U);
1085                                 ++rxData;
1086                             }
1087                             remainingReceiveByteCount -= 2U;
1088                         }
1089                         else
1090                         {
1091                             if (rxData != NULL)
1092                             {
1093                                 *(rxData) = (uint8_t)wordReceived;
1094                                 ++rxData;
1095                             }
1096                             remainingReceiveByteCount--;
1097                         }
1098                         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoDrainRequestFlag);
1099                     }
1100                 }
1101             }
1102             else
1103             {
1104                 /*Wait until Tx Fifo is not full*/
1105                 while (0U == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
1106                 {
1107                     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1108                 }
1109 
1110                 if (txData != NULL)
1111                 {
1112                     wordToSend = *(txData);
1113                     ++txData;
1114                     wordToSend |= (uint16_t)(*(txData)) << 8U;
1115                     ++txData;
1116                 }
1117                 else
1118                 {
1119                     wordToSend = dummyData;
1120                 }
1121                 base->PUSHR = command | wordToSend;
1122                 remainingSendByteCount -= 2U;
1123 
1124                 DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1125 
1126                 while (((remainingReceiveByteCount - remainingSendByteCount) / 2U) >= fifoSize)
1127                 {
1128                     if ((uint32_t)kDSPI_RxFifoDrainRequestFlag ==
1129                         (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoDrainRequestFlag))
1130                     {
1131                         wordReceived = (uint16_t)DSPI_ReadData(base);
1132 
1133                         if (rxData != NULL)
1134                         {
1135                             *rxData = (uint8_t)wordReceived;
1136                             ++rxData;
1137                             *rxData = (uint8_t)(wordReceived >> 8U);
1138                             ++rxData;
1139                         }
1140                         remainingReceiveByteCount -= 2U;
1141 
1142                         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoDrainRequestFlag);
1143                     }
1144                 }
1145             }
1146         }
1147     }
1148 
1149     return kStatus_Success;
1150 }
1151 
DSPI_MasterTransferPrepare(SPI_Type * base,dspi_master_handle_t * handle,dspi_transfer_t * transfer)1152 static void DSPI_MasterTransferPrepare(SPI_Type *base, dspi_master_handle_t *handle, dspi_transfer_t *transfer)
1153 {
1154     assert(NULL != handle);
1155     assert(NULL != transfer);
1156 
1157     uint32_t tmpMCR                          = 0;
1158     dspi_command_data_config_t commandStruct = {false, (uint8_t)kDSPI_Ctar0, (uint8_t)kDSPI_Pcs0, false, false};
1159 
1160     DSPI_StopTransfer(base);
1161     DSPI_FlushFifo(base, true, true);
1162     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_AllStatusFlag);
1163 
1164     commandStruct.whichPcs =
1165         (uint8_t)((uint32_t)1U << ((transfer->configFlags & DSPI_MASTER_PCS_MASK) >> DSPI_MASTER_PCS_SHIFT));
1166     commandStruct.isEndOfQueue       = false;
1167     commandStruct.clearTransferCount = false;
1168     commandStruct.whichCtar = (uint8_t)((transfer->configFlags & DSPI_MASTER_CTAR_MASK) >> DSPI_MASTER_CTAR_SHIFT);
1169     commandStruct.isPcsContinuous =
1170         (0U != (transfer->configFlags & (uint32_t)kDSPI_MasterPcsContinuous)) ? true : false;
1171     handle->command = DSPI_MasterGetFormattedCommand(&(commandStruct));
1172 
1173     commandStruct.isEndOfQueue = true;
1174     commandStruct.isPcsContinuous =
1175         (0U != (transfer->configFlags & (uint32_t)kDSPI_MasterActiveAfterTransfer)) ? true : false;
1176     handle->lastCommand = DSPI_MasterGetFormattedCommand(&(commandStruct));
1177 
1178     handle->bitsPerFrame = ((base->CTAR[commandStruct.whichCtar] & SPI_CTAR_FMSZ_MASK) >> SPI_CTAR_FMSZ_SHIFT) + 1U;
1179 
1180     tmpMCR = base->MCR;
1181     if ((0U != (tmpMCR & SPI_MCR_DIS_RXF_MASK)) || (0U != (tmpMCR & SPI_MCR_DIS_TXF_MASK)))
1182     {
1183         handle->fifoSize = 1U;
1184     }
1185     else
1186     {
1187         handle->fifoSize = (uint8_t)FSL_FEATURE_DSPI_FIFO_SIZEn(base);
1188     }
1189     handle->txData                    = transfer->txData;
1190     handle->rxData                    = transfer->rxData;
1191     handle->remainingSendByteCount    = transfer->dataSize;
1192     handle->remainingReceiveByteCount = transfer->dataSize;
1193     handle->totalByteCount            = transfer->dataSize;
1194 }
1195 
1196 /*!
1197  * brief DSPI master transfer data using interrupts.
1198  *
1199  * This function transfers data using interrupts. This is a non-blocking function, which returns right away. When all
1200  * data is transferred, the callback function is called.
1201 
1202  * param base DSPI peripheral base address.
1203  * param handle Pointer to the dspi_master_handle_t structure which stores the transfer state.
1204  * param transfer Pointer to the dspi_transfer_t structure.
1205  * return status of status_t.
1206  */
DSPI_MasterTransferNonBlocking(SPI_Type * base,dspi_master_handle_t * handle,dspi_transfer_t * transfer)1207 status_t DSPI_MasterTransferNonBlocking(SPI_Type *base, dspi_master_handle_t *handle, dspi_transfer_t *transfer)
1208 {
1209     assert(NULL != handle);
1210     assert(NULL != transfer);
1211 
1212     /* If the transfer count is zero, then return immediately.*/
1213     if (transfer->dataSize == 0U)
1214     {
1215         return kStatus_InvalidArgument;
1216     }
1217 
1218     /* Check that we're not busy.*/
1219     if (handle->state == (uint8_t)kDSPI_Busy)
1220     {
1221         return kStatus_DSPI_Busy;
1222     }
1223 
1224     handle->state = (uint8_t)kDSPI_Busy;
1225 
1226     /* Disable the NVIC for DSPI peripheral. */
1227     (void)DisableIRQ(s_dspiIRQ[DSPI_GetInstance(base)]);
1228 
1229     DSPI_MasterTransferPrepare(base, handle, transfer);
1230 
1231     /* RX FIFO Drain request: RFDF_RE to enable RFDF interrupt
1232      * Since SPI is a synchronous interface, we only need to enable the RX interrupt.
1233      * The IRQ handler will get the status of RX and TX interrupt flags.
1234      */
1235     s_dspiMasterIsr = DSPI_MasterTransferHandleIRQ;
1236 
1237     DSPI_EnableInterrupts(base, (uint32_t)kDSPI_RxFifoDrainRequestInterruptEnable);
1238     DSPI_StartTransfer(base);
1239 
1240     /* Fill up the Tx FIFO to trigger the transfer. */
1241     DSPI_MasterTransferFillUpTxFifo(base, handle);
1242 
1243     /* Enable the NVIC for DSPI peripheral. */
1244     (void)EnableIRQ(s_dspiIRQ[DSPI_GetInstance(base)]);
1245 
1246     return kStatus_Success;
1247 }
1248 
1249 /*!
1250  * brief Transfers a block of data using a polling method.
1251  *
1252  * This function will do a half-duplex transfer for DSPI master, This is a blocking function,
1253  * which does not retuen until all transfer have been completed. And data transfer will be half-duplex,
1254  * users can set transmit first or receive first.
1255  *
1256  * param base DSPI base pointer
1257  * param xfer pointer to dspi_half_duplex_transfer_t structure
1258  * return status of status_t.
1259  */
DSPI_MasterHalfDuplexTransferBlocking(SPI_Type * base,dspi_half_duplex_transfer_t * xfer)1260 status_t DSPI_MasterHalfDuplexTransferBlocking(SPI_Type *base, dspi_half_duplex_transfer_t *xfer)
1261 {
1262     assert(NULL != xfer);
1263 
1264     dspi_transfer_t tempXfer = {0};
1265     status_t status;
1266 
1267     if (true == xfer->isTransmitFirst)
1268     {
1269         tempXfer.txData   = xfer->txData;
1270         tempXfer.rxData   = NULL;
1271         tempXfer.dataSize = xfer->txDataSize;
1272     }
1273     else
1274     {
1275         tempXfer.txData   = NULL;
1276         tempXfer.rxData   = xfer->rxData;
1277         tempXfer.dataSize = xfer->rxDataSize;
1278     }
1279     /* If the pcs pin keep assert between transmit and receive. */
1280     if (true == xfer->isPcsAssertInTransfer)
1281     {
1282         tempXfer.configFlags = (xfer->configFlags) | (uint32_t)kDSPI_MasterActiveAfterTransfer;
1283     }
1284     else
1285     {
1286         tempXfer.configFlags = (xfer->configFlags) & (~(uint32_t)kDSPI_MasterActiveAfterTransfer);
1287     }
1288 
1289     status = DSPI_MasterTransferBlocking(base, &tempXfer);
1290     if (status != kStatus_Success)
1291     {
1292         return status;
1293     }
1294 
1295     if (true == xfer->isTransmitFirst)
1296     {
1297         tempXfer.txData   = NULL;
1298         tempXfer.rxData   = xfer->rxData;
1299         tempXfer.dataSize = xfer->rxDataSize;
1300     }
1301     else
1302     {
1303         tempXfer.txData   = xfer->txData;
1304         tempXfer.rxData   = NULL;
1305         tempXfer.dataSize = xfer->txDataSize;
1306     }
1307     tempXfer.configFlags = xfer->configFlags;
1308 
1309     /* DSPI transfer blocking. */
1310     status = DSPI_MasterTransferBlocking(base, &tempXfer);
1311 
1312     return status;
1313 }
1314 
1315 /*!
1316  * brief Performs a non-blocking DSPI interrupt transfer.
1317  *
1318  * This function transfers data using interrupts, the transfer mechanism is half-duplex. This is a non-blocking
1319  * function,
1320  * which returns right away. When all data is transferred, the callback function is called.
1321  *
1322  * param base DSPI peripheral base address.
1323  * param handle pointer to dspi_master_handle_t structure which stores the transfer state
1324  * param xfer pointer to dspi_half_duplex_transfer_t structure
1325  * return status of status_t.
1326  */
DSPI_MasterHalfDuplexTransferNonBlocking(SPI_Type * base,dspi_master_handle_t * handle,dspi_half_duplex_transfer_t * xfer)1327 status_t DSPI_MasterHalfDuplexTransferNonBlocking(SPI_Type *base,
1328                                                   dspi_master_handle_t *handle,
1329                                                   dspi_half_duplex_transfer_t *xfer)
1330 {
1331     assert(NULL != xfer);
1332     assert(NULL != handle);
1333     dspi_transfer_t tempXfer = {0};
1334     status_t status;
1335 
1336     if (true == xfer->isTransmitFirst)
1337     {
1338         tempXfer.txData   = xfer->txData;
1339         tempXfer.rxData   = NULL;
1340         tempXfer.dataSize = xfer->txDataSize;
1341     }
1342     else
1343     {
1344         tempXfer.txData   = NULL;
1345         tempXfer.rxData   = xfer->rxData;
1346         tempXfer.dataSize = xfer->rxDataSize;
1347     }
1348     /* If the pcs pin keep assert between transmit and receive. */
1349     if (true == xfer->isPcsAssertInTransfer)
1350     {
1351         tempXfer.configFlags = (xfer->configFlags) | (uint32_t)kDSPI_MasterActiveAfterTransfer;
1352     }
1353     else
1354     {
1355         tempXfer.configFlags = (xfer->configFlags) & (~(uint32_t)kDSPI_MasterActiveAfterTransfer);
1356     }
1357 
1358     status = DSPI_MasterTransferBlocking(base, &tempXfer);
1359     if (status != kStatus_Success)
1360     {
1361         return status;
1362     }
1363 
1364     if (true == xfer->isTransmitFirst)
1365     {
1366         tempXfer.txData   = NULL;
1367         tempXfer.rxData   = xfer->rxData;
1368         tempXfer.dataSize = xfer->rxDataSize;
1369     }
1370     else
1371     {
1372         tempXfer.txData   = xfer->txData;
1373         tempXfer.rxData   = NULL;
1374         tempXfer.dataSize = xfer->txDataSize;
1375     }
1376     tempXfer.configFlags = xfer->configFlags;
1377 
1378     status = DSPI_MasterTransferNonBlocking(base, handle, &tempXfer);
1379 
1380     return status;
1381 }
1382 
1383 /*!
1384  * brief Gets the master transfer count.
1385  *
1386  * This function gets the master transfer count.
1387  *
1388  * param base DSPI peripheral base address.
1389  * param handle Pointer to the dspi_master_handle_t structure which stores the transfer state.
1390  * param count The number of bytes transferred by using the non-blocking transaction.
1391  * return status of status_t.
1392  */
DSPI_MasterTransferGetCount(SPI_Type * base,dspi_master_handle_t * handle,size_t * count)1393 status_t DSPI_MasterTransferGetCount(SPI_Type *base, dspi_master_handle_t *handle, size_t *count)
1394 {
1395     assert(NULL != handle);
1396 
1397     if (NULL == count)
1398     {
1399         return kStatus_InvalidArgument;
1400     }
1401 
1402     /* Catch when there is not an active transfer. */
1403     if (handle->state != (uint8_t)kDSPI_Busy)
1404     {
1405         *count = 0;
1406         return kStatus_NoTransferInProgress;
1407     }
1408 
1409     *count = handle->totalByteCount - handle->remainingReceiveByteCount;
1410     return kStatus_Success;
1411 }
1412 
DSPI_MasterTransferComplete(SPI_Type * base,dspi_master_handle_t * handle)1413 static void DSPI_MasterTransferComplete(SPI_Type *base, dspi_master_handle_t *handle)
1414 {
1415     assert(NULL != handle);
1416 
1417     /* Disable interrupt requests*/
1418     DSPI_DisableInterrupts(
1419         base, ((uint32_t)kDSPI_RxFifoDrainRequestInterruptEnable | (uint32_t)kDSPI_TxFifoFillRequestInterruptEnable));
1420 
1421     status_t status = 0;
1422     if (handle->state == (uint8_t)kDSPI_Error)
1423     {
1424         status = kStatus_DSPI_Error;
1425     }
1426     else
1427     {
1428         status = kStatus_Success;
1429     }
1430 
1431     if ((NULL != handle->callback) && ((uint8_t)kDSPI_Idle != handle->state))
1432     {
1433         handle->state = (uint8_t)kDSPI_Idle;
1434         handle->callback(base, handle, status, handle->userData);
1435     }
1436 }
1437 
DSPI_MasterTransferFillUpTxFifo(SPI_Type * base,dspi_master_handle_t * handle)1438 static void DSPI_MasterTransferFillUpTxFifo(SPI_Type *base, dspi_master_handle_t *handle)
1439 {
1440     assert(NULL != handle);
1441 
1442     uint16_t wordToSend                 = 0;
1443     uint8_t dummyData                   = DSPI_GetDummyDataInstance(base);
1444     size_t tmpRemainingSendByteCount    = handle->remainingSendByteCount;
1445     size_t tmpRemainingReceiveByteCount = handle->remainingReceiveByteCount;
1446     uint8_t tmpFifoSize                 = handle->fifoSize;
1447 
1448     /* If bits/frame is greater than one byte */
1449     if (handle->bitsPerFrame > 8U)
1450     {
1451         /* Fill the fifo until it is full or until the send word count is 0 or until the difference
1452          * between the remainingReceiveByteCount and remainingSendByteCount equals the FIFO depth.
1453          * The reason for checking the difference is to ensure we only send as much as the
1454          * RX FIFO can receive.
1455          * For this case where bitsPerFrame > 8, each entry in the FIFO contains 2 bytes of the
1456          * send data, hence the difference between the remainingReceiveByteCount and
1457          * remainingSendByteCount must be divided by 2 to convert this difference into a
1458          * 16-bit (2 byte) value.
1459          */
1460         while ((0U != (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag)) &&
1461                (((tmpRemainingReceiveByteCount - tmpRemainingSendByteCount) / 2U) < tmpFifoSize))
1462         {
1463             if (handle->remainingSendByteCount <= 2U)
1464             {
1465                 if (NULL != handle->txData)
1466                 {
1467                     if (handle->remainingSendByteCount == 1U)
1468                     {
1469                         wordToSend = *(handle->txData);
1470                     }
1471                     else
1472                     {
1473                         wordToSend = *(handle->txData);
1474                         ++handle->txData; /* increment to next data byte */
1475                         wordToSend |= (uint16_t)(*(handle->txData)) << 8U;
1476                     }
1477                 }
1478                 else
1479                 {
1480                     wordToSend = dummyData;
1481                 }
1482                 handle->remainingSendByteCount = 0;
1483                 base->PUSHR                    = handle->lastCommand | wordToSend;
1484             }
1485             /* For all words except the last word */
1486             else
1487             {
1488                 if (NULL != handle->txData)
1489                 {
1490                     wordToSend = *(handle->txData);
1491                     ++handle->txData; /* increment to next data byte */
1492                     wordToSend |= (uint16_t)(*(handle->txData)) << 8U;
1493                     ++handle->txData; /* increment to next data byte */
1494                 }
1495                 else
1496                 {
1497                     wordToSend = dummyData;
1498                 }
1499                 handle->remainingSendByteCount -= 2U; /* decrement remainingSendByteCount by 2 */
1500                 base->PUSHR = handle->command | wordToSend;
1501             }
1502 
1503             /* Try to clear the TFFF; if the TX FIFO is full this will clear */
1504             DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1505 
1506             /* exit loop if send count is zero, else update local variables for next loop.
1507              * If this is the first time write to the PUSHR, write only once.
1508              */
1509             tmpRemainingSendByteCount = handle->remainingSendByteCount;
1510             if ((tmpRemainingSendByteCount == 0U) || (tmpRemainingSendByteCount == handle->totalByteCount - 2U))
1511             {
1512                 break;
1513             }
1514             tmpRemainingReceiveByteCount = handle->remainingReceiveByteCount;
1515             tmpRemainingSendByteCount    = handle->remainingSendByteCount;
1516             tmpFifoSize                  = handle->fifoSize;
1517         } /* End of TX FIFO fill while loop */
1518     }
1519     /* Optimized for bits/frame less than or equal to one byte. */
1520     else
1521     {
1522         /* Fill the fifo until it is full or until the send word count is 0 or until the difference
1523          * between the remainingReceiveByteCount and remainingSendByteCount equals the FIFO depth.
1524          * The reason for checking the difference is to ensure we only send as much as the
1525          * RX FIFO can receive.
1526          */
1527         while ((0U != (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag)) &&
1528                ((tmpRemainingReceiveByteCount - tmpRemainingSendByteCount) < tmpFifoSize))
1529         {
1530             if (NULL != handle->txData)
1531             {
1532                 wordToSend = *(handle->txData);
1533                 ++handle->txData;
1534             }
1535             else
1536             {
1537                 wordToSend = dummyData;
1538             }
1539 
1540             if (handle->remainingSendByteCount == 1U)
1541             {
1542                 base->PUSHR = handle->lastCommand | wordToSend;
1543             }
1544             else
1545             {
1546                 base->PUSHR = handle->command | wordToSend;
1547             }
1548 
1549             /* Try to clear the TFFF; if the TX FIFO is full this will clear */
1550             DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1551 
1552             --handle->remainingSendByteCount;
1553 
1554             /* exit loop if send count is zero, else update local variables for next loop
1555              * If this is the first time write to the PUSHR, write only once.
1556              */
1557             tmpRemainingSendByteCount = handle->remainingSendByteCount;
1558             if ((tmpRemainingSendByteCount == 0U) || (tmpRemainingSendByteCount == (handle->totalByteCount - 1U)))
1559             {
1560                 break;
1561             }
1562             tmpRemainingReceiveByteCount = handle->remainingReceiveByteCount;
1563             tmpRemainingSendByteCount    = handle->remainingSendByteCount;
1564             tmpFifoSize                  = handle->fifoSize;
1565         }
1566     }
1567 }
1568 
1569 /*!
1570  * brief DSPI master aborts a transfer using an interrupt.
1571  *
1572  * This function aborts a transfer using an interrupt.
1573  *
1574  * param base DSPI peripheral base address.
1575  * param handle Pointer to the dspi_master_handle_t structure which stores the transfer state.
1576  */
DSPI_MasterTransferAbort(SPI_Type * base,dspi_master_handle_t * handle)1577 void DSPI_MasterTransferAbort(SPI_Type *base, dspi_master_handle_t *handle)
1578 {
1579     assert(NULL != handle);
1580 
1581     DSPI_StopTransfer(base);
1582 
1583     /* Disable interrupt requests*/
1584     DSPI_DisableInterrupts(
1585         base, ((uint32_t)kDSPI_RxFifoDrainRequestInterruptEnable | (uint32_t)kDSPI_TxFifoFillRequestInterruptEnable));
1586 
1587     handle->state = (uint8_t)kDSPI_Idle;
1588 }
1589 
1590 /*!
1591  * brief DSPI Master IRQ handler function.
1592  *
1593  * This function processes the DSPI transmit and receive IRQ.
1594 
1595  * param base DSPI peripheral base address.
1596  * param handle Pointer to the dspi_master_handle_t structure which stores the transfer state.
1597  */
DSPI_MasterTransferHandleIRQ(SPI_Type * base,dspi_master_handle_t * handle)1598 void DSPI_MasterTransferHandleIRQ(SPI_Type *base, dspi_master_handle_t *handle)
1599 {
1600     assert(NULL != handle);
1601 
1602     /* RECEIVE IRQ handler: Check read buffer only if there are remaining bytes to read. */
1603     if (0U != (handle->remainingReceiveByteCount))
1604     {
1605         /* Check read buffer.*/
1606         uint16_t wordReceived; /* Maximum supported data bit length in master mode is 16-bits */
1607 
1608         /* If bits/frame is greater than one byte */
1609         if (handle->bitsPerFrame > 8U)
1610         {
1611             while ((uint32_t)kDSPI_RxFifoDrainRequestFlag ==
1612                    (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoDrainRequestFlag))
1613             {
1614                 wordReceived = (uint16_t)DSPI_ReadData(base);
1615                 /* clear the rx fifo drain request, needed for non-DMA applications as this flag
1616                  * will remain set even if the rx fifo is empty. By manually clearing this flag, it
1617                  * either remain clear if no more data is in the fifo, or it will set if there is
1618                  * more data in the fifo.
1619                  */
1620                 DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoDrainRequestFlag);
1621 
1622                 /* Store read bytes into rx buffer only if a buffer pointer was provided */
1623                 if (NULL != handle->rxData)
1624                 {
1625                     /* For the last word received, if there is an extra byte due to the odd transfer
1626                      * byte count, only save the last byte and discard the upper byte
1627                      */
1628                     if (handle->remainingReceiveByteCount == 1U)
1629                     {
1630                         *handle->rxData = (uint8_t)wordReceived; /* Write first data byte */
1631                         --handle->remainingReceiveByteCount;
1632                     }
1633                     else
1634                     {
1635                         *handle->rxData = (uint8_t)wordReceived;         /* Write first data byte */
1636                         ++handle->rxData;                                /* increment to next data byte */
1637                         *handle->rxData = (uint8_t)(wordReceived >> 8U); /* Write second data byte */
1638                         ++handle->rxData;                                /* increment to next data byte */
1639                         handle->remainingReceiveByteCount -= 2U;
1640                     }
1641                 }
1642                 else
1643                 {
1644                     if (handle->remainingReceiveByteCount == 1U)
1645                     {
1646                         --handle->remainingReceiveByteCount;
1647                     }
1648                     else
1649                     {
1650                         handle->remainingReceiveByteCount -= 2U;
1651                     }
1652                 }
1653                 if (handle->remainingReceiveByteCount == 0U)
1654                 {
1655                     break;
1656                 }
1657             } /* End of RX FIFO drain while loop */
1658         }
1659         /* Optimized for bits/frame less than or equal to one byte. */
1660         else
1661         {
1662             while ((uint32_t)kDSPI_RxFifoDrainRequestFlag ==
1663                    (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoDrainRequestFlag))
1664             {
1665                 wordReceived = (uint16_t)DSPI_ReadData(base);
1666                 /* clear the rx fifo drain request, needed for non-DMA applications as this flag
1667                  * will remain set even if the rx fifo is empty. By manually clearing this flag, it
1668                  * either remain clear if no more data is in the fifo, or it will set if there is
1669                  * more data in the fifo.
1670                  */
1671                 DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoDrainRequestFlag);
1672 
1673                 /* Store read bytes into rx buffer only if a buffer pointer was provided */
1674                 if (NULL != handle->rxData)
1675                 {
1676                     *handle->rxData = (uint8_t)wordReceived;
1677                     ++handle->rxData;
1678                 }
1679 
1680                 --handle->remainingReceiveByteCount;
1681 
1682                 if (handle->remainingReceiveByteCount == 0U)
1683                 {
1684                     break;
1685                 }
1686             } /* End of RX FIFO drain while loop */
1687         }
1688     }
1689 
1690     /* Check write buffer. We always have to send a word in order to keep the transfer
1691      * moving. So if the caller didn't provide a send buffer, we just send a zero.
1692      */
1693     if (0U != (handle->remainingSendByteCount))
1694     {
1695         DSPI_MasterTransferFillUpTxFifo(base, handle);
1696     }
1697 
1698     /* Check if we're done with this transfer.*/
1699     if (handle->remainingSendByteCount == 0U)
1700     {
1701         if (handle->remainingReceiveByteCount == 0U)
1702         {
1703             /* Complete the transfer and disable the interrupts */
1704             DSPI_MasterTransferComplete(base, handle);
1705         }
1706     }
1707 }
1708 
1709 /*Transactional APIs -- Slave*/
1710 /*!
1711  * brief Initializes the DSPI slave handle.
1712  *
1713  * This function initializes the DSPI handle, which can be used for other DSPI transactional APIs.  Usually, for a
1714  * specified DSPI instance, call this API once to get the initialized handle.
1715  *
1716  * param handle DSPI handle pointer to the dspi_slave_handle_t.
1717  * param base DSPI peripheral base address.
1718  * param callback DSPI callback.
1719  * param userData Callback function parameter.
1720  */
DSPI_SlaveTransferCreateHandle(SPI_Type * base,dspi_slave_handle_t * handle,dspi_slave_transfer_callback_t callback,void * userData)1721 void DSPI_SlaveTransferCreateHandle(SPI_Type *base,
1722                                     dspi_slave_handle_t *handle,
1723                                     dspi_slave_transfer_callback_t callback,
1724                                     void *userData)
1725 {
1726     assert(NULL != handle);
1727 
1728     /* Zero the handle. */
1729     (void)memset(handle, 0, sizeof(*handle));
1730 
1731     g_dspiHandle[DSPI_GetInstance(base)] = handle;
1732 
1733     handle->callback = callback;
1734     handle->userData = userData;
1735 }
1736 
1737 /*!
1738  * brief DSPI slave transfers data using an interrupt.
1739  *
1740  * This function transfers data using an interrupt. This is a non-blocking function, which returns right away. When all
1741  * data is transferred, the callback function is called.
1742  *
1743  * param base DSPI peripheral base address.
1744  * param handle Pointer to the dspi_slave_handle_t structure which stores the transfer state.
1745  * param transfer Pointer to the dspi_transfer_t structure.
1746  * return status of status_t.
1747  */
DSPI_SlaveTransferNonBlocking(SPI_Type * base,dspi_slave_handle_t * handle,dspi_transfer_t * transfer)1748 status_t DSPI_SlaveTransferNonBlocking(SPI_Type *base, dspi_slave_handle_t *handle, dspi_transfer_t *transfer)
1749 {
1750     assert(NULL != handle);
1751     assert(NULL != transfer);
1752 
1753     /* If receive length is zero */
1754     if (transfer->dataSize == 0U)
1755     {
1756         return kStatus_InvalidArgument;
1757     }
1758 
1759     /* If both send buffer and receive buffer is null */
1760     if ((NULL == (transfer->txData)) && (NULL == (transfer->rxData)))
1761     {
1762         return kStatus_InvalidArgument;
1763     }
1764 
1765     /* Check that we're not busy.*/
1766     if (handle->state == (uint8_t)kDSPI_Busy)
1767     {
1768         return kStatus_DSPI_Busy;
1769     }
1770     handle->state = (uint8_t)kDSPI_Busy;
1771 
1772     /* Enable the NVIC for DSPI peripheral. */
1773     (void)EnableIRQ(s_dspiIRQ[DSPI_GetInstance(base)]);
1774 
1775     /* Store transfer information */
1776     handle->txData                    = transfer->txData;
1777     handle->rxData                    = transfer->rxData;
1778     handle->remainingSendByteCount    = transfer->dataSize;
1779     handle->remainingReceiveByteCount = transfer->dataSize;
1780     handle->totalByteCount            = transfer->dataSize;
1781 
1782     handle->errorCount = 0;
1783 
1784     uint8_t whichCtar = (uint8_t)((transfer->configFlags & DSPI_SLAVE_CTAR_MASK) >> DSPI_SLAVE_CTAR_SHIFT);
1785     handle->bitsPerFrame =
1786         (((base->CTAR_SLAVE[whichCtar]) & SPI_CTAR_SLAVE_FMSZ_MASK) >> SPI_CTAR_SLAVE_FMSZ_SHIFT) + 1U;
1787 
1788     DSPI_StopTransfer(base);
1789 
1790     DSPI_FlushFifo(base, true, true);
1791     DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_AllStatusFlag);
1792 
1793     s_dspiSlaveIsr = DSPI_SlaveTransferHandleIRQ;
1794 
1795     /* Enable RX FIFO drain request, the slave only use this interrupt */
1796     DSPI_EnableInterrupts(base, (uint32_t)kDSPI_RxFifoDrainRequestInterruptEnable);
1797 
1798     if (NULL != handle->rxData)
1799     {
1800         /* RX FIFO overflow request enable */
1801         DSPI_EnableInterrupts(base, (uint32_t)kDSPI_RxFifoOverflowInterruptEnable);
1802     }
1803     if (NULL != handle->txData)
1804     {
1805         /* TX FIFO underflow request enable */
1806         DSPI_EnableInterrupts(base, (uint32_t)kDSPI_TxFifoUnderflowInterruptEnable);
1807     }
1808 
1809     DSPI_StartTransfer(base);
1810 
1811     /* Prepare data to transmit */
1812     DSPI_SlaveTransferFillUpTxFifo(base, handle);
1813 
1814     return kStatus_Success;
1815 }
1816 
1817 /*!
1818  * brief Gets the slave transfer count.
1819  *
1820  * This function gets the slave transfer count.
1821  *
1822  * param base DSPI peripheral base address.
1823  * param handle Pointer to the dspi_master_handle_t structure which stores the transfer state.
1824  * param count The number of bytes transferred by using the non-blocking transaction.
1825  * return status of status_t.
1826  */
DSPI_SlaveTransferGetCount(SPI_Type * base,dspi_slave_handle_t * handle,size_t * count)1827 status_t DSPI_SlaveTransferGetCount(SPI_Type *base, dspi_slave_handle_t *handle, size_t *count)
1828 {
1829     assert(NULL != handle);
1830 
1831     if (NULL == count)
1832     {
1833         return kStatus_InvalidArgument;
1834     }
1835 
1836     /* Catch when there is not an active transfer. */
1837     if (handle->state != (uint8_t)kDSPI_Busy)
1838     {
1839         *count = 0;
1840         return kStatus_NoTransferInProgress;
1841     }
1842 
1843     *count = handle->totalByteCount - handle->remainingReceiveByteCount;
1844     return kStatus_Success;
1845 }
1846 
DSPI_SlaveTransferFillUpTxFifo(SPI_Type * base,dspi_slave_handle_t * handle)1847 static void DSPI_SlaveTransferFillUpTxFifo(SPI_Type *base, dspi_slave_handle_t *handle)
1848 {
1849     assert(NULL != handle);
1850 
1851     uint16_t transmitData = 0;
1852     uint8_t dummyPattern  = DSPI_GetDummyDataInstance(base);
1853 
1854     /* Service the transmitter, if transmit buffer provided, transmit the data,
1855      * else transmit dummy pattern
1856      */
1857     while ((uint32_t)kDSPI_TxFifoFillRequestFlag == (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoFillRequestFlag))
1858     {
1859         /* Transmit data */
1860         if (handle->remainingSendByteCount > 0U)
1861         {
1862             /* Have data to transmit, update the transmit data and push to FIFO */
1863             if (handle->bitsPerFrame <= 8U)
1864             {
1865                 /* bits/frame is 1 byte */
1866                 if (NULL != handle->txData)
1867                 {
1868                     /* Update transmit data and transmit pointer */
1869                     transmitData = *handle->txData;
1870                     handle->txData++;
1871                 }
1872                 else
1873                 {
1874                     transmitData = dummyPattern;
1875                 }
1876 
1877                 /* Decrease remaining dataSize */
1878                 --handle->remainingSendByteCount;
1879             }
1880             /* bits/frame is 2 bytes */
1881             else
1882             {
1883                 /* With multibytes per frame transmission, the transmit frame contains data from
1884                  * transmit buffer until sent dataSize matches user request. Other bytes will set to
1885                  * dummy pattern value.
1886                  */
1887                 if (NULL != handle->txData)
1888                 {
1889                     /* Update first byte of transmit data and transmit pointer */
1890                     transmitData = *handle->txData;
1891                     handle->txData++;
1892 
1893                     if (handle->remainingSendByteCount == 1U)
1894                     {
1895                         /* Decrease remaining dataSize */
1896                         --handle->remainingSendByteCount;
1897                         /* Update second byte of transmit data to second byte of dummy pattern */
1898                         transmitData = transmitData | (uint16_t)(((uint16_t)dummyPattern) << 8U);
1899                     }
1900                     else
1901                     {
1902                         /* Update second byte of transmit data and transmit pointer */
1903                         transmitData = transmitData | (uint16_t)((uint16_t)(*handle->txData) << 8U);
1904                         handle->txData++;
1905                         handle->remainingSendByteCount -= 2U;
1906                     }
1907                 }
1908                 else
1909                 {
1910                     if (handle->remainingSendByteCount == 1U)
1911                     {
1912                         --handle->remainingSendByteCount;
1913                     }
1914                     else
1915                     {
1916                         handle->remainingSendByteCount -= 2U;
1917                     }
1918                     transmitData = (uint16_t)((uint16_t)(dummyPattern) << 8U) | dummyPattern;
1919                 }
1920             }
1921         }
1922         else
1923         {
1924             break;
1925         }
1926 
1927         /* Write the data to the DSPI data register */
1928         base->PUSHR_SLAVE = transmitData;
1929 
1930         /* Try to clear TFFF by writing a one to it; it will not clear if TX FIFO not full */
1931         DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
1932     }
1933 }
1934 
DSPI_SlaveTransferComplete(SPI_Type * base,dspi_slave_handle_t * handle)1935 static void DSPI_SlaveTransferComplete(SPI_Type *base, dspi_slave_handle_t *handle)
1936 {
1937     assert(NULL != handle);
1938 
1939     /* Disable interrupt requests */
1940     DSPI_DisableInterrupts(
1941         base, ((uint32_t)kDSPI_TxFifoUnderflowInterruptEnable | (uint32_t)kDSPI_TxFifoFillRequestInterruptEnable |
1942                (uint32_t)kDSPI_RxFifoOverflowInterruptEnable | (uint32_t)kDSPI_RxFifoDrainRequestInterruptEnable));
1943 
1944     /* The transfer is complete. */
1945     handle->txData                    = NULL;
1946     handle->rxData                    = NULL;
1947     handle->remainingReceiveByteCount = 0;
1948     handle->remainingSendByteCount    = 0;
1949 
1950     status_t status;
1951     if (handle->state == (uint8_t)kDSPI_Error)
1952     {
1953         status = kStatus_DSPI_Error;
1954     }
1955     else
1956     {
1957         status = kStatus_Success;
1958     }
1959 
1960     handle->state = (uint8_t)kDSPI_Idle;
1961 
1962     if (NULL != handle->callback)
1963     {
1964         handle->callback(base, handle, status, handle->userData);
1965     }
1966 }
1967 
1968 /*!
1969  * brief DSPI slave aborts a transfer using an interrupt.
1970  *
1971  * This function aborts a transfer using an interrupt.
1972  *
1973  * param base DSPI peripheral base address.
1974  * param handle Pointer to the dspi_slave_handle_t structure which stores the transfer state.
1975  */
DSPI_SlaveTransferAbort(SPI_Type * base,dspi_slave_handle_t * handle)1976 void DSPI_SlaveTransferAbort(SPI_Type *base, dspi_slave_handle_t *handle)
1977 {
1978     assert(NULL != handle);
1979 
1980     DSPI_StopTransfer(base);
1981 
1982     /* Disable interrupt requests */
1983     DSPI_DisableInterrupts(
1984         base, ((uint32_t)kDSPI_TxFifoUnderflowInterruptEnable | (uint32_t)kDSPI_TxFifoFillRequestInterruptEnable |
1985                (uint32_t)kDSPI_RxFifoOverflowInterruptEnable | (uint32_t)kDSPI_RxFifoDrainRequestInterruptEnable));
1986 
1987     handle->state                     = (uint8_t)kDSPI_Idle;
1988     handle->remainingSendByteCount    = 0;
1989     handle->remainingReceiveByteCount = 0;
1990 }
1991 
1992 /*!
1993  * brief DSPI Master IRQ handler function.
1994  *
1995  * This function processes the DSPI transmit and receive IRQ.
1996  *
1997  * param base DSPI peripheral base address.
1998  * param handle Pointer to the dspi_slave_handle_t structure which stores the transfer state.
1999  */
DSPI_SlaveTransferHandleIRQ(SPI_Type * base,dspi_slave_handle_t * handle)2000 void DSPI_SlaveTransferHandleIRQ(SPI_Type *base, dspi_slave_handle_t *handle)
2001 {
2002     assert(NULL != handle);
2003 
2004     uint8_t dummyPattern = DSPI_GetDummyDataInstance(base);
2005     uint32_t dataReceived;
2006     uint32_t dataSend                     = 0;
2007     uint32_t tmpRemainingReceiveByteCount = 0;
2008 
2009     /* Because SPI protocol is synchronous, the number of bytes that that slave received from the
2010      * master is the actual number of bytes that the slave transmitted to the master. So we only
2011      * monitor the received dataSize to know when the transfer is complete.
2012      */
2013     if (handle->remainingReceiveByteCount > 0U)
2014     {
2015         while ((uint32_t)kDSPI_RxFifoDrainRequestFlag ==
2016                (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoDrainRequestFlag))
2017         {
2018             /* Have received data in the buffer. */
2019             dataReceived = base->POPR;
2020             /*Clear the rx fifo drain request, needed for non-DMA applications as this flag
2021              * will remain set even if the rx fifo is empty. By manually clearing this flag, it
2022              * either remain clear if no more data is in the fifo, or it will set if there is
2023              * more data in the fifo.
2024              */
2025             DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoDrainRequestFlag);
2026 
2027             /* If bits/frame is one byte */
2028             if (handle->bitsPerFrame <= 8U)
2029             {
2030                 if (NULL != handle->rxData)
2031                 {
2032                     /* Receive buffer is not null, store data into it */
2033                     *handle->rxData = (uint8_t)dataReceived;
2034                     ++handle->rxData;
2035                 }
2036                 /* Descrease remaining receive byte count */
2037                 --handle->remainingReceiveByteCount;
2038 
2039                 if (handle->remainingSendByteCount > 0U)
2040                 {
2041                     if (NULL != handle->txData)
2042                     {
2043                         dataSend = *handle->txData;
2044                         ++handle->txData;
2045                     }
2046                     else
2047                     {
2048                         dataSend = dummyPattern;
2049                     }
2050 
2051                     --handle->remainingSendByteCount;
2052                     /* Write the data to the DSPI data register */
2053                     base->PUSHR_SLAVE = dataSend;
2054                 }
2055             }
2056             else /* If bits/frame is 2 bytes */
2057             {
2058                 /* With multibytes frame receiving, we only receive till the received dataSize
2059                  * matches user request. Other bytes will be ignored.
2060                  */
2061                 if (NULL != handle->rxData)
2062                 {
2063                     /* Receive buffer is not null, store first byte into it */
2064                     *handle->rxData = (uint8_t)dataReceived;
2065                     ++handle->rxData;
2066 
2067                     if (handle->remainingReceiveByteCount == 1U)
2068                     {
2069                         /* Decrease remaining receive byte count */
2070                         --handle->remainingReceiveByteCount;
2071                     }
2072                     else
2073                     {
2074                         /* Receive buffer is not null, store second byte into it */
2075                         *handle->rxData = (uint8_t)(dataReceived >> 8U);
2076                         ++handle->rxData;
2077                         handle->remainingReceiveByteCount -= 2U;
2078                     }
2079                 }
2080                 /* If no handle->rxData*/
2081                 else
2082                 {
2083                     if (handle->remainingReceiveByteCount == 1U)
2084                     {
2085                         /* Decrease remaining receive byte count */
2086                         --handle->remainingReceiveByteCount;
2087                     }
2088                     else
2089                     {
2090                         handle->remainingReceiveByteCount -= 2U;
2091                     }
2092                 }
2093 
2094                 if (handle->remainingSendByteCount > 0U)
2095                 {
2096                     if (NULL != handle->txData)
2097                     {
2098                         dataSend = *handle->txData;
2099                         ++handle->txData;
2100 
2101                         if (handle->remainingSendByteCount == 1U)
2102                         {
2103                             --handle->remainingSendByteCount;
2104                             dataSend |= (uint16_t)((uint16_t)(dummyPattern) << 8U);
2105                         }
2106                         else
2107                         {
2108                             dataSend |= (uint32_t)(*handle->txData) << 8U;
2109                             ++handle->txData;
2110                             handle->remainingSendByteCount -= 2U;
2111                         }
2112                     }
2113                     /* If no handle->txData*/
2114                     else
2115                     {
2116                         if (handle->remainingSendByteCount == 1U)
2117                         {
2118                             --handle->remainingSendByteCount;
2119                         }
2120                         else
2121                         {
2122                             handle->remainingSendByteCount -= 2U;
2123                         }
2124                         dataSend = ((uint32_t)(dummyPattern) << 8U) | dummyPattern;
2125                     }
2126                     /* Write the data to the DSPI data register */
2127                     base->PUSHR_SLAVE = dataSend;
2128                 }
2129             }
2130             /* Try to clear TFFF by writing a one to it; it will not clear if TX FIFO not full */
2131             DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoFillRequestFlag);
2132 
2133             if (handle->remainingReceiveByteCount == 0U)
2134             {
2135                 break;
2136             }
2137         }
2138     }
2139     /* Check if remaining receive byte count matches user request */
2140     tmpRemainingReceiveByteCount = handle->remainingReceiveByteCount;
2141     if ((handle->state == (uint8_t)(kDSPI_Error)) || (tmpRemainingReceiveByteCount == 0U))
2142     {
2143         /* Other cases, stop the transfer. */
2144         DSPI_SlaveTransferComplete(base, handle);
2145         return;
2146     }
2147 
2148     /* Catch tx fifo underflow conditions, service only if tx under flow interrupt enabled */
2149     if (0U != (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_TxFifoUnderflowFlag))
2150     {
2151         if (0U != (base->RSER & SPI_RSER_TFUF_RE_MASK))
2152         {
2153             DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_TxFifoUnderflowFlag);
2154             /* Change state to error and clear flag */
2155             if (NULL != handle->txData)
2156             {
2157                 handle->state = (uint8_t)kDSPI_Error;
2158             }
2159             handle->errorCount++;
2160         }
2161     }
2162 
2163     /* Catch rx fifo overflow conditions, service only if rx over flow interrupt enabled */
2164     if (0U != (DSPI_GetStatusFlags(base) & (uint32_t)kDSPI_RxFifoOverflowFlag))
2165     {
2166         if (0U != (base->RSER & SPI_RSER_RFOF_RE_MASK))
2167         {
2168             DSPI_ClearStatusFlags(base, (uint32_t)kDSPI_RxFifoOverflowFlag);
2169             /* Change state to error and clear flag */
2170             if (NULL != handle->txData)
2171             {
2172                 handle->state = (uint8_t)kDSPI_Error;
2173             }
2174             handle->errorCount++;
2175         }
2176     }
2177 }
2178 
DSPI_CommonIRQHandler(SPI_Type * base,void * param)2179 static void DSPI_CommonIRQHandler(SPI_Type *base, void *param)
2180 {
2181     if (DSPI_IsMaster(base))
2182     {
2183         s_dspiMasterIsr(base, (dspi_master_handle_t *)param);
2184     }
2185     else
2186     {
2187         s_dspiSlaveIsr(base, (dspi_slave_handle_t *)param);
2188     }
2189     SDK_ISR_EXIT_BARRIER;
2190 }
2191 
2192 #if defined(SPI0)
2193 void SPI0_DriverIRQHandler(void);
SPI0_DriverIRQHandler(void)2194 void SPI0_DriverIRQHandler(void)
2195 {
2196     assert(NULL != g_dspiHandle[0]);
2197     DSPI_CommonIRQHandler(SPI0, g_dspiHandle[0]);
2198 }
2199 #endif
2200 
2201 #if defined(SPI1)
2202 void SPI1_DriverIRQHandler(void);
SPI1_DriverIRQHandler(void)2203 void SPI1_DriverIRQHandler(void)
2204 {
2205     assert(NULL != g_dspiHandle[1]);
2206     DSPI_CommonIRQHandler(SPI1, g_dspiHandle[1]);
2207 }
2208 #endif
2209 
2210 #if defined(SPI2)
2211 void SPI2_DriverIRQHandler(void);
SPI2_DriverIRQHandler(void)2212 void SPI2_DriverIRQHandler(void)
2213 {
2214     assert(NULL != g_dspiHandle[2]);
2215     DSPI_CommonIRQHandler(SPI2, g_dspiHandle[2]);
2216 }
2217 #endif
2218 
2219 #if defined(SPI3)
2220 void SPI3_DriverIRQHandler(void);
SPI3_DriverIRQHandler(void)2221 void SPI3_DriverIRQHandler(void)
2222 {
2223     assert(NULL != g_dspiHandle[3]);
2224     DSPI_CommonIRQHandler(SPI3, g_dspiHandle[3]);
2225 }
2226 #endif
2227 
2228 #if defined(SPI4)
2229 void SPI4_DriverIRQHandler(void);
SPI4_DriverIRQHandler(void)2230 void SPI4_DriverIRQHandler(void)
2231 {
2232     assert(NULL != g_dspiHandle[4]);
2233     DSPI_CommonIRQHandler(SPI4, g_dspiHandle[4]);
2234 }
2235 #endif
2236 
2237 #if defined(SPI5)
2238 void SPI5_DriverIRQHandler(void);
SPI5_DriverIRQHandler(void)2239 void SPI5_DriverIRQHandler(void)
2240 {
2241     assert(NULL != g_dspiHandle[5]);
2242     DSPI_CommonIRQHandler(SPI5, g_dspiHandle[5]);
2243 }
2244 #endif
2245 
2246 #if (FSL_FEATURE_SOC_DSPI_COUNT > 6)
2247 #error "Should write the SPIx_DriverIRQHandler function that instance greater than 5 !"
2248 #endif
2249