1*150812a8SEvalZero /*
2*150812a8SEvalZero * Copyright (c) 2015 - 2018, Nordic Semiconductor ASA
3*150812a8SEvalZero * All rights reserved.
4*150812a8SEvalZero *
5*150812a8SEvalZero * Redistribution and use in source and binary forms, with or without
6*150812a8SEvalZero * modification, are permitted provided that the following conditions are met:
7*150812a8SEvalZero *
8*150812a8SEvalZero * 1. Redistributions of source code must retain the above copyright notice, this
9*150812a8SEvalZero * list of conditions and the following disclaimer.
10*150812a8SEvalZero *
11*150812a8SEvalZero * 2. Redistributions in binary form must reproduce the above copyright
12*150812a8SEvalZero * notice, this list of conditions and the following disclaimer in the
13*150812a8SEvalZero * documentation and/or other materials provided with the distribution.
14*150812a8SEvalZero *
15*150812a8SEvalZero * 3. Neither the name of the copyright holder nor the names of its
16*150812a8SEvalZero * contributors may be used to endorse or promote products derived from this
17*150812a8SEvalZero * software without specific prior written permission.
18*150812a8SEvalZero *
19*150812a8SEvalZero * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
20*150812a8SEvalZero * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
21*150812a8SEvalZero * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
22*150812a8SEvalZero * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
23*150812a8SEvalZero * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
24*150812a8SEvalZero * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
25*150812a8SEvalZero * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
26*150812a8SEvalZero * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
27*150812a8SEvalZero * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
28*150812a8SEvalZero * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
29*150812a8SEvalZero * POSSIBILITY OF SUCH DAMAGE.
30*150812a8SEvalZero */
31*150812a8SEvalZero
32*150812a8SEvalZero #ifndef NRF_SPIM_H__
33*150812a8SEvalZero #define NRF_SPIM_H__
34*150812a8SEvalZero
35*150812a8SEvalZero #include <nrfx.h>
36*150812a8SEvalZero
37*150812a8SEvalZero #ifdef __cplusplus
38*150812a8SEvalZero extern "C" {
39*150812a8SEvalZero #endif
40*150812a8SEvalZero
41*150812a8SEvalZero /**
42*150812a8SEvalZero * @defgroup nrf_spim_hal SPIM HAL
43*150812a8SEvalZero * @{
44*150812a8SEvalZero * @ingroup nrf_spim
45*150812a8SEvalZero * @brief Hardware access layer for managing the SPIM peripheral.
46*150812a8SEvalZero */
47*150812a8SEvalZero
48*150812a8SEvalZero /**
49*150812a8SEvalZero * @brief This value can be used as a parameter for the @ref nrf_spim_pins_set
50*150812a8SEvalZero * function to specify that a given SPI signal (SCK, MOSI, or MISO)
51*150812a8SEvalZero * shall not be connected to a physical pin.
52*150812a8SEvalZero */
53*150812a8SEvalZero #define NRF_SPIM_PIN_NOT_CONNECTED 0xFFFFFFFF
54*150812a8SEvalZero
55*150812a8SEvalZero #if defined(SPIM_DCXCNT_DCXCNT_Msk) || defined(__NRFX_DOXYGEN__)
56*150812a8SEvalZero /**
57*150812a8SEvalZero * @brief This value specified in the DCX line configuration causes this line
58*150812a8SEvalZero * to be set low during whole transmission (all transmitted bytes are
59*150812a8SEvalZero * marked as command bytes). Any lower value causes the DCX line to be
60*150812a8SEvalZero * switched from low to high after this number of bytes is transmitted
61*150812a8SEvalZero * (all remaining bytes are marked as data bytes).
62*150812a8SEvalZero */
63*150812a8SEvalZero #define NRF_SPIM_DCX_CNT_ALL_CMD 0xF
64*150812a8SEvalZero #endif
65*150812a8SEvalZero
66*150812a8SEvalZero #define NRF_SPIM_HW_CSN_PRESENT \
67*150812a8SEvalZero (NRFX_CHECK(SPIM0_FEATURE_HARDWARE_CSN_PRESENT) || \
68*150812a8SEvalZero NRFX_CHECK(SPIM1_FEATURE_HARDWARE_CSN_PRESENT) || \
69*150812a8SEvalZero NRFX_CHECK(SPIM2_FEATURE_HARDWARE_CSN_PRESENT) || \
70*150812a8SEvalZero NRFX_CHECK(SPIM3_FEATURE_HARDWARE_CSN_PRESENT))
71*150812a8SEvalZero
72*150812a8SEvalZero /**
73*150812a8SEvalZero * @brief SPIM tasks.
74*150812a8SEvalZero */
75*150812a8SEvalZero typedef enum
76*150812a8SEvalZero {
77*150812a8SEvalZero /*lint -save -e30*/
78*150812a8SEvalZero NRF_SPIM_TASK_START = offsetof(NRF_SPIM_Type, TASKS_START), ///< Start SPI transaction.
79*150812a8SEvalZero NRF_SPIM_TASK_STOP = offsetof(NRF_SPIM_Type, TASKS_STOP), ///< Stop SPI transaction.
80*150812a8SEvalZero NRF_SPIM_TASK_SUSPEND = offsetof(NRF_SPIM_Type, TASKS_SUSPEND), ///< Suspend SPI transaction.
81*150812a8SEvalZero NRF_SPIM_TASK_RESUME = offsetof(NRF_SPIM_Type, TASKS_RESUME) ///< Resume SPI transaction.
82*150812a8SEvalZero /*lint -restore*/
83*150812a8SEvalZero } nrf_spim_task_t;
84*150812a8SEvalZero
85*150812a8SEvalZero /**
86*150812a8SEvalZero * @brief SPIM events.
87*150812a8SEvalZero */
88*150812a8SEvalZero typedef enum
89*150812a8SEvalZero {
90*150812a8SEvalZero /*lint -save -e30*/
91*150812a8SEvalZero NRF_SPIM_EVENT_STOPPED = offsetof(NRF_SPIM_Type, EVENTS_STOPPED), ///< SPI transaction has stopped.
92*150812a8SEvalZero NRF_SPIM_EVENT_ENDRX = offsetof(NRF_SPIM_Type, EVENTS_ENDRX), ///< End of RXD buffer reached.
93*150812a8SEvalZero NRF_SPIM_EVENT_END = offsetof(NRF_SPIM_Type, EVENTS_END), ///< End of RXD buffer and TXD buffer reached.
94*150812a8SEvalZero NRF_SPIM_EVENT_ENDTX = offsetof(NRF_SPIM_Type, EVENTS_ENDTX), ///< End of TXD buffer reached.
95*150812a8SEvalZero NRF_SPIM_EVENT_STARTED = offsetof(NRF_SPIM_Type, EVENTS_STARTED) ///< Transaction started.
96*150812a8SEvalZero /*lint -restore*/
97*150812a8SEvalZero } nrf_spim_event_t;
98*150812a8SEvalZero
99*150812a8SEvalZero /**
100*150812a8SEvalZero * @brief SPIM shortcuts.
101*150812a8SEvalZero */
102*150812a8SEvalZero typedef enum
103*150812a8SEvalZero {
104*150812a8SEvalZero NRF_SPIM_SHORT_END_START_MASK = SPIM_SHORTS_END_START_Msk, ///< Shortcut between END event and START task.
105*150812a8SEvalZero NRF_SPIM_ALL_SHORTS_MASK = SPIM_SHORTS_END_START_Msk ///< All SPIM shortcuts.
106*150812a8SEvalZero } nrf_spim_short_mask_t;
107*150812a8SEvalZero
108*150812a8SEvalZero /**
109*150812a8SEvalZero * @brief SPIM interrupts.
110*150812a8SEvalZero */
111*150812a8SEvalZero typedef enum
112*150812a8SEvalZero {
113*150812a8SEvalZero NRF_SPIM_INT_STOPPED_MASK = SPIM_INTENSET_STOPPED_Msk, ///< Interrupt on STOPPED event.
114*150812a8SEvalZero NRF_SPIM_INT_ENDRX_MASK = SPIM_INTENSET_ENDRX_Msk, ///< Interrupt on ENDRX event.
115*150812a8SEvalZero NRF_SPIM_INT_END_MASK = SPIM_INTENSET_END_Msk, ///< Interrupt on END event.
116*150812a8SEvalZero NRF_SPIM_INT_ENDTX_MASK = SPIM_INTENSET_ENDTX_Msk, ///< Interrupt on ENDTX event.
117*150812a8SEvalZero NRF_SPIM_INT_STARTED_MASK = SPIM_INTENSET_STARTED_Msk, ///< Interrupt on STARTED event.
118*150812a8SEvalZero NRF_SPIM_ALL_INTS_MASK = SPIM_INTENSET_STOPPED_Msk |
119*150812a8SEvalZero SPIM_INTENSET_ENDRX_Msk |
120*150812a8SEvalZero SPIM_INTENSET_END_Msk |
121*150812a8SEvalZero SPIM_INTENSET_ENDTX_Msk |
122*150812a8SEvalZero SPIM_INTENSET_STARTED_Msk ///< All SPIM interrupts.
123*150812a8SEvalZero } nrf_spim_int_mask_t;
124*150812a8SEvalZero
125*150812a8SEvalZero /**
126*150812a8SEvalZero * @brief SPI master data rates.
127*150812a8SEvalZero */
128*150812a8SEvalZero typedef enum
129*150812a8SEvalZero {
130*150812a8SEvalZero NRF_SPIM_FREQ_125K = SPIM_FREQUENCY_FREQUENCY_K125, ///< 125 kbps.
131*150812a8SEvalZero NRF_SPIM_FREQ_250K = SPIM_FREQUENCY_FREQUENCY_K250, ///< 250 kbps.
132*150812a8SEvalZero NRF_SPIM_FREQ_500K = SPIM_FREQUENCY_FREQUENCY_K500, ///< 500 kbps.
133*150812a8SEvalZero NRF_SPIM_FREQ_1M = SPIM_FREQUENCY_FREQUENCY_M1, ///< 1 Mbps.
134*150812a8SEvalZero NRF_SPIM_FREQ_2M = SPIM_FREQUENCY_FREQUENCY_M2, ///< 2 Mbps.
135*150812a8SEvalZero NRF_SPIM_FREQ_4M = SPIM_FREQUENCY_FREQUENCY_M4, ///< 4 Mbps.
136*150812a8SEvalZero // [conversion to 'int' needed to prevent compilers from complaining
137*150812a8SEvalZero // that the provided value (0x80000000UL) is out of range of "int"]
138*150812a8SEvalZero NRF_SPIM_FREQ_8M = (int)SPIM_FREQUENCY_FREQUENCY_M8, ///< 8 Mbps.
139*150812a8SEvalZero #if defined(SPIM_FREQUENCY_FREQUENCY_M16) || defined(__NRFX_DOXYGEN__)
140*150812a8SEvalZero NRF_SPIM_FREQ_16M = SPIM_FREQUENCY_FREQUENCY_M16, ///< 16 Mbps.
141*150812a8SEvalZero #endif
142*150812a8SEvalZero #if defined(SPIM_FREQUENCY_FREQUENCY_M32) || defined(__NRFX_DOXYGEN__)
143*150812a8SEvalZero NRF_SPIM_FREQ_32M = SPIM_FREQUENCY_FREQUENCY_M32 ///< 32 Mbps.
144*150812a8SEvalZero #endif
145*150812a8SEvalZero } nrf_spim_frequency_t;
146*150812a8SEvalZero
147*150812a8SEvalZero /**
148*150812a8SEvalZero * @brief SPI modes.
149*150812a8SEvalZero */
150*150812a8SEvalZero typedef enum
151*150812a8SEvalZero {
152*150812a8SEvalZero NRF_SPIM_MODE_0, ///< SCK active high, sample on leading edge of clock.
153*150812a8SEvalZero NRF_SPIM_MODE_1, ///< SCK active high, sample on trailing edge of clock.
154*150812a8SEvalZero NRF_SPIM_MODE_2, ///< SCK active low, sample on leading edge of clock.
155*150812a8SEvalZero NRF_SPIM_MODE_3 ///< SCK active low, sample on trailing edge of clock.
156*150812a8SEvalZero } nrf_spim_mode_t;
157*150812a8SEvalZero
158*150812a8SEvalZero /**
159*150812a8SEvalZero * @brief SPI bit orders.
160*150812a8SEvalZero */
161*150812a8SEvalZero typedef enum
162*150812a8SEvalZero {
163*150812a8SEvalZero NRF_SPIM_BIT_ORDER_MSB_FIRST = SPIM_CONFIG_ORDER_MsbFirst, ///< Most significant bit shifted out first.
164*150812a8SEvalZero NRF_SPIM_BIT_ORDER_LSB_FIRST = SPIM_CONFIG_ORDER_LsbFirst ///< Least significant bit shifted out first.
165*150812a8SEvalZero } nrf_spim_bit_order_t;
166*150812a8SEvalZero
167*150812a8SEvalZero #if (NRF_SPIM_HW_CSN_PRESENT) || defined(__NRFX_DOXYGEN__)
168*150812a8SEvalZero /**
169*150812a8SEvalZero * @brief SPI CSN pin polarity.
170*150812a8SEvalZero */
171*150812a8SEvalZero typedef enum
172*150812a8SEvalZero {
173*150812a8SEvalZero NRF_SPIM_CSN_POL_LOW = SPIM_CSNPOL_CSNPOL_LOW, ///< Active low (idle state high).
174*150812a8SEvalZero NRF_SPIM_CSN_POL_HIGH = SPIM_CSNPOL_CSNPOL_HIGH ///< Active high (idle state low).
175*150812a8SEvalZero } nrf_spim_csn_pol_t;
176*150812a8SEvalZero #endif // (NRF_SPIM_HW_CSN_PRESENT) || defined(__NRFX_DOXYGEN__)
177*150812a8SEvalZero
178*150812a8SEvalZero /**
179*150812a8SEvalZero * @brief Function for activating a specific SPIM task.
180*150812a8SEvalZero *
181*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
182*150812a8SEvalZero * @param[in] spim_task Task to activate.
183*150812a8SEvalZero */
184*150812a8SEvalZero __STATIC_INLINE void nrf_spim_task_trigger(NRF_SPIM_Type * p_reg,
185*150812a8SEvalZero nrf_spim_task_t spim_task);
186*150812a8SEvalZero
187*150812a8SEvalZero /**
188*150812a8SEvalZero * @brief Function for getting the address of a specific SPIM task register.
189*150812a8SEvalZero *
190*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
191*150812a8SEvalZero * @param[in] spim_task Requested task.
192*150812a8SEvalZero *
193*150812a8SEvalZero * @return Address of the specified task register.
194*150812a8SEvalZero */
195*150812a8SEvalZero __STATIC_INLINE uint32_t nrf_spim_task_address_get(NRF_SPIM_Type * p_reg,
196*150812a8SEvalZero nrf_spim_task_t spim_task);
197*150812a8SEvalZero
198*150812a8SEvalZero /**
199*150812a8SEvalZero * @brief Function for clearing a specific SPIM event.
200*150812a8SEvalZero *
201*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
202*150812a8SEvalZero * @param[in] spim_event Event to clear.
203*150812a8SEvalZero */
204*150812a8SEvalZero __STATIC_INLINE void nrf_spim_event_clear(NRF_SPIM_Type * p_reg,
205*150812a8SEvalZero nrf_spim_event_t spim_event);
206*150812a8SEvalZero
207*150812a8SEvalZero /**
208*150812a8SEvalZero * @brief Function for checking the state of a specific SPIM event.
209*150812a8SEvalZero *
210*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
211*150812a8SEvalZero * @param[in] spim_event Event to check.
212*150812a8SEvalZero *
213*150812a8SEvalZero * @retval true If the event is set.
214*150812a8SEvalZero * @retval false If the event is not set.
215*150812a8SEvalZero */
216*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_event_check(NRF_SPIM_Type * p_reg,
217*150812a8SEvalZero nrf_spim_event_t spim_event);
218*150812a8SEvalZero
219*150812a8SEvalZero /**
220*150812a8SEvalZero * @brief Function for getting the address of a specific SPIM event register.
221*150812a8SEvalZero *
222*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
223*150812a8SEvalZero * @param[in] spim_event Requested event.
224*150812a8SEvalZero *
225*150812a8SEvalZero * @return Address of the specified event register.
226*150812a8SEvalZero */
227*150812a8SEvalZero __STATIC_INLINE uint32_t nrf_spim_event_address_get(NRF_SPIM_Type * p_reg,
228*150812a8SEvalZero nrf_spim_event_t spim_event);
229*150812a8SEvalZero /**
230*150812a8SEvalZero * @brief Function for enabling specified shortcuts.
231*150812a8SEvalZero *
232*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
233*150812a8SEvalZero * @param[in] spim_shorts_mask Shortcuts to enable.
234*150812a8SEvalZero */
235*150812a8SEvalZero __STATIC_INLINE void nrf_spim_shorts_enable(NRF_SPIM_Type * p_reg,
236*150812a8SEvalZero uint32_t spim_shorts_mask);
237*150812a8SEvalZero
238*150812a8SEvalZero /**
239*150812a8SEvalZero * @brief Function for disabling specified shortcuts.
240*150812a8SEvalZero *
241*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
242*150812a8SEvalZero * @param[in] spim_shorts_mask Shortcuts to disable.
243*150812a8SEvalZero */
244*150812a8SEvalZero __STATIC_INLINE void nrf_spim_shorts_disable(NRF_SPIM_Type * p_reg,
245*150812a8SEvalZero uint32_t spim_shorts_mask);
246*150812a8SEvalZero
247*150812a8SEvalZero /**
248*150812a8SEvalZero * @brief Function for getting shorts setting.
249*150812a8SEvalZero *
250*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
251*150812a8SEvalZero */
252*150812a8SEvalZero __STATIC_INLINE uint32_t nrf_spim_shorts_get(NRF_SPIM_Type * p_reg);
253*150812a8SEvalZero
254*150812a8SEvalZero /**
255*150812a8SEvalZero * @brief Function for enabling specified interrupts.
256*150812a8SEvalZero *
257*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
258*150812a8SEvalZero * @param[in] spim_int_mask Interrupts to enable.
259*150812a8SEvalZero */
260*150812a8SEvalZero __STATIC_INLINE void nrf_spim_int_enable(NRF_SPIM_Type * p_reg,
261*150812a8SEvalZero uint32_t spim_int_mask);
262*150812a8SEvalZero
263*150812a8SEvalZero /**
264*150812a8SEvalZero * @brief Function for disabling specified interrupts.
265*150812a8SEvalZero *
266*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
267*150812a8SEvalZero * @param[in] spim_int_mask Interrupts to disable.
268*150812a8SEvalZero */
269*150812a8SEvalZero __STATIC_INLINE void nrf_spim_int_disable(NRF_SPIM_Type * p_reg,
270*150812a8SEvalZero uint32_t spim_int_mask);
271*150812a8SEvalZero
272*150812a8SEvalZero /**
273*150812a8SEvalZero * @brief Function for retrieving the state of a given interrupt.
274*150812a8SEvalZero *
275*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
276*150812a8SEvalZero * @param[in] spim_int Interrupt to check.
277*150812a8SEvalZero *
278*150812a8SEvalZero * @retval true If the interrupt is enabled.
279*150812a8SEvalZero * @retval false If the interrupt is not enabled.
280*150812a8SEvalZero */
281*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_int_enable_check(NRF_SPIM_Type * p_reg,
282*150812a8SEvalZero nrf_spim_int_mask_t spim_int);
283*150812a8SEvalZero
284*150812a8SEvalZero #if defined(DPPI_PRESENT) || defined(__NRFX_DOXYGEN__)
285*150812a8SEvalZero /**
286*150812a8SEvalZero * @brief Function for setting the subscribe configuration for a given
287*150812a8SEvalZero * SPIM task.
288*150812a8SEvalZero *
289*150812a8SEvalZero * @param[in] p_reg Pointer to the structure of registers of the peripheral.
290*150812a8SEvalZero * @param[in] task Task for which to set the configuration.
291*150812a8SEvalZero * @param[in] channel Channel through which to subscribe events.
292*150812a8SEvalZero */
293*150812a8SEvalZero __STATIC_INLINE void nrf_spim_subscribe_set(NRF_SPIM_Type * p_reg,
294*150812a8SEvalZero nrf_spim_task_t task,
295*150812a8SEvalZero uint8_t channel);
296*150812a8SEvalZero
297*150812a8SEvalZero /**
298*150812a8SEvalZero * @brief Function for clearing the subscribe configuration for a given
299*150812a8SEvalZero * SPIM task.
300*150812a8SEvalZero *
301*150812a8SEvalZero * @param[in] p_reg Pointer to the structure of registers of the peripheral.
302*150812a8SEvalZero * @param[in] task Task for which to clear the configuration.
303*150812a8SEvalZero */
304*150812a8SEvalZero __STATIC_INLINE void nrf_spim_subscribe_clear(NRF_SPIM_Type * p_reg,
305*150812a8SEvalZero nrf_spim_task_t task);
306*150812a8SEvalZero
307*150812a8SEvalZero /**
308*150812a8SEvalZero * @brief Function for setting the publish configuration for a given
309*150812a8SEvalZero * SPIM event.
310*150812a8SEvalZero *
311*150812a8SEvalZero * @param[in] p_reg Pointer to the structure of registers of the peripheral.
312*150812a8SEvalZero * @param[in] event Event for which to set the configuration.
313*150812a8SEvalZero * @param[in] channel Channel through which to publish the event.
314*150812a8SEvalZero */
315*150812a8SEvalZero __STATIC_INLINE void nrf_spim_publish_set(NRF_SPIM_Type * p_reg,
316*150812a8SEvalZero nrf_spim_event_t event,
317*150812a8SEvalZero uint8_t channel);
318*150812a8SEvalZero
319*150812a8SEvalZero /**
320*150812a8SEvalZero * @brief Function for clearing the publish configuration for a given
321*150812a8SEvalZero * SPIM event.
322*150812a8SEvalZero *
323*150812a8SEvalZero * @param[in] p_reg Pointer to the structure of registers of the peripheral.
324*150812a8SEvalZero * @param[in] event Event for which to clear the configuration.
325*150812a8SEvalZero */
326*150812a8SEvalZero __STATIC_INLINE void nrf_spim_publish_clear(NRF_SPIM_Type * p_reg,
327*150812a8SEvalZero nrf_spim_event_t event);
328*150812a8SEvalZero #endif // defined(DPPI_PRESENT) || defined(__NRFX_DOXYGEN__)
329*150812a8SEvalZero
330*150812a8SEvalZero /**
331*150812a8SEvalZero * @brief Function for enabling the SPIM peripheral.
332*150812a8SEvalZero *
333*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
334*150812a8SEvalZero */
335*150812a8SEvalZero __STATIC_INLINE void nrf_spim_enable(NRF_SPIM_Type * p_reg);
336*150812a8SEvalZero
337*150812a8SEvalZero /**
338*150812a8SEvalZero * @brief Function for disabling the SPIM peripheral.
339*150812a8SEvalZero *
340*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
341*150812a8SEvalZero */
342*150812a8SEvalZero __STATIC_INLINE void nrf_spim_disable(NRF_SPIM_Type * p_reg);
343*150812a8SEvalZero
344*150812a8SEvalZero /**
345*150812a8SEvalZero * @brief Function for configuring SPIM pins.
346*150812a8SEvalZero *
347*150812a8SEvalZero * If a given signal is not needed, pass the @ref NRF_SPIM_PIN_NOT_CONNECTED
348*150812a8SEvalZero * value instead of its pin number.
349*150812a8SEvalZero *
350*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
351*150812a8SEvalZero * @param[in] sck_pin SCK pin number.
352*150812a8SEvalZero * @param[in] mosi_pin MOSI pin number.
353*150812a8SEvalZero * @param[in] miso_pin MISO pin number.
354*150812a8SEvalZero */
355*150812a8SEvalZero __STATIC_INLINE void nrf_spim_pins_set(NRF_SPIM_Type * p_reg,
356*150812a8SEvalZero uint32_t sck_pin,
357*150812a8SEvalZero uint32_t mosi_pin,
358*150812a8SEvalZero uint32_t miso_pin);
359*150812a8SEvalZero
360*150812a8SEvalZero #if (NRF_SPIM_HW_CSN_PRESENT) || defined(__NRFX_DOXYGEN__)
361*150812a8SEvalZero /**
362*150812a8SEvalZero * @brief Function for configuring the SPIM hardware CSN pin.
363*150812a8SEvalZero *
364*150812a8SEvalZero * If this signal is not needed, pass the @ref NRF_SPIM_PIN_NOT_CONNECTED
365*150812a8SEvalZero * value instead of its pin number.
366*150812a8SEvalZero *
367*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
368*150812a8SEvalZero * @param[in] pin CSN pin number.
369*150812a8SEvalZero * @param[in] polarity CSN pin polarity.
370*150812a8SEvalZero * @param[in] duration Minimum duration between the edge of CSN and the edge of SCK
371*150812a8SEvalZero * and minimum duration of CSN must stay unselected between transactions.
372*150812a8SEvalZero * The value is specified in number of 64 MHz clock cycles (15.625 ns).
373*150812a8SEvalZero */
374*150812a8SEvalZero __STATIC_INLINE void nrf_spim_csn_configure(NRF_SPIM_Type * p_reg,
375*150812a8SEvalZero uint32_t pin,
376*150812a8SEvalZero nrf_spim_csn_pol_t polarity,
377*150812a8SEvalZero uint32_t duration);
378*150812a8SEvalZero #endif // (NRF_SPIM_HW_CSN_PRESENT) || defined(__NRFX_DOXYGEN__)
379*150812a8SEvalZero
380*150812a8SEvalZero #if defined(SPIM_PSELDCX_CONNECT_Msk) || defined(__NRFX_DOXYGEN__)
381*150812a8SEvalZero /**
382*150812a8SEvalZero * @brief Function for configuring the SPIM DCX pin.
383*150812a8SEvalZero *
384*150812a8SEvalZero * If this signal is not needed, pass the @ref NRF_SPIM_PIN_NOT_CONNECTED
385*150812a8SEvalZero * value instead of its pin number.
386*150812a8SEvalZero *
387*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
388*150812a8SEvalZero * @param[in] dcx_pin DCX pin number.
389*150812a8SEvalZero */
390*150812a8SEvalZero __STATIC_INLINE void nrf_spim_dcx_pin_set(NRF_SPIM_Type * p_reg,
391*150812a8SEvalZero uint32_t dcx_pin);
392*150812a8SEvalZero
393*150812a8SEvalZero /**
394*150812a8SEvalZero * @brief Function for configuring the number of command bytes.
395*150812a8SEvalZero *
396*150812a8SEvalZero * Maximum value available for dividing the transmitted bytes into command
397*150812a8SEvalZero * bytes and data bytes is @ref NRF_SPIM_DCX_CNT_ALL_CMD - 1.
398*150812a8SEvalZero * The @ref NRF_SPIM_DCX_CNT_ALL_CMD value passed as the @c count parameter
399*150812a8SEvalZero * causes all transmitted bytes to be marked as command bytes.
400*150812a8SEvalZero *
401*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
402*150812a8SEvalZero * @param[in] count Number of command bytes preceding the data bytes.
403*150812a8SEvalZero */
404*150812a8SEvalZero __STATIC_INLINE void nrf_spim_dcx_cnt_set(NRF_SPIM_Type * p_reg,
405*150812a8SEvalZero uint32_t count);
406*150812a8SEvalZero #endif // defined(SPIM_PSELDCX_CONNECT_Msk) || defined(__NRFX_DOXYGEN__)
407*150812a8SEvalZero
408*150812a8SEvalZero #if defined(SPIM_IFTIMING_RXDELAY_RXDELAY_Msk) || defined(__NRFX_DOXYGEN__)
409*150812a8SEvalZero /**
410*150812a8SEvalZero * @brief Function for configuring the extended SPIM interface.
411*150812a8SEvalZero * @param p_reg Pointer to the peripheral registers structure.
412*150812a8SEvalZero * @param rxdelay Sample delay for input serial data on MISO,
413*150812a8SEvalZero * specified in 64 MHz clock cycles (15.625 ns) from the sampling edge of SCK.
414*150812a8SEvalZero */
415*150812a8SEvalZero __STATIC_INLINE void nrf_spim_iftiming_set(NRF_SPIM_Type * p_reg,
416*150812a8SEvalZero uint32_t rxdelay);
417*150812a8SEvalZero #endif // defined(SPIM_IFTIMING_RXDELAY_RXDELAY_Msk) || defined(__NRFX_DOXYGEN__)
418*150812a8SEvalZero
419*150812a8SEvalZero #if defined(SPIM_STALLSTAT_RX_Msk) || defined(__NRFX_DOXYGEN__)
420*150812a8SEvalZero /**
421*150812a8SEvalZero * @brief Function for clearing stall status for RX EasyDMA RAM accesses.
422*150812a8SEvalZero *
423*150812a8SEvalZero * @param p_reg Pointer to the peripheral registers structure.
424*150812a8SEvalZero */
425*150812a8SEvalZero __STATIC_INLINE void nrf_spim_stallstat_rx_clear(NRF_SPIM_Type * p_reg);
426*150812a8SEvalZero
427*150812a8SEvalZero /**
428*150812a8SEvalZero * @brief Function for getting stall status for RX EasyDMA RAM accesses.
429*150812a8SEvalZero *
430*150812a8SEvalZero * @param p_reg Pointer to the peripheral registers structure.
431*150812a8SEvalZero *
432*150812a8SEvalZero * @return Stall status of RX EasyDMA RAM accesses.
433*150812a8SEvalZero */
434*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_stallstat_rx_get(NRF_SPIM_Type * p_reg);
435*150812a8SEvalZero #endif // defined(SPIM_STALLSTAT_RX_Msk) || defined(__NRFX_DOXYGEN__)
436*150812a8SEvalZero
437*150812a8SEvalZero #if defined(SPIM_STALLSTAT_TX_Msk) || defined(__NRFX_DOXYGEN__)
438*150812a8SEvalZero /**
439*150812a8SEvalZero * @brief Function for clearing stall status for TX EasyDMA RAM accesses.
440*150812a8SEvalZero *
441*150812a8SEvalZero * @param p_reg Pointer to the peripheral registers structure.
442*150812a8SEvalZero */
443*150812a8SEvalZero __STATIC_INLINE void nrf_spim_stallstat_tx_clear(NRF_SPIM_Type * p_reg);
444*150812a8SEvalZero
445*150812a8SEvalZero /**
446*150812a8SEvalZero * @brief Function for getting stall status for TX EasyDMA RAM accesses.
447*150812a8SEvalZero *
448*150812a8SEvalZero * @param p_reg Pointer to the peripheral registers structure.
449*150812a8SEvalZero *
450*150812a8SEvalZero * @return Stall status of TX EasyDMA RAM accesses.
451*150812a8SEvalZero */
452*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_stallstat_tx_get(NRF_SPIM_Type * p_reg);
453*150812a8SEvalZero #endif // defined(SPIM_STALLSTAT_TX_Msk) || defined(__NRFX_DOXYGEN__)
454*150812a8SEvalZero
455*150812a8SEvalZero /**
456*150812a8SEvalZero * @brief Function for setting the SPI master data rate.
457*150812a8SEvalZero *
458*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
459*150812a8SEvalZero * @param[in] frequency SPI frequency.
460*150812a8SEvalZero */
461*150812a8SEvalZero __STATIC_INLINE void nrf_spim_frequency_set(NRF_SPIM_Type * p_reg,
462*150812a8SEvalZero nrf_spim_frequency_t frequency);
463*150812a8SEvalZero
464*150812a8SEvalZero /**
465*150812a8SEvalZero * @brief Function for setting the transmit buffer.
466*150812a8SEvalZero *
467*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
468*150812a8SEvalZero * @param[in] p_buffer Pointer to the buffer with data to send.
469*150812a8SEvalZero * @param[in] length Maximum number of data bytes to transmit.
470*150812a8SEvalZero */
471*150812a8SEvalZero __STATIC_INLINE void nrf_spim_tx_buffer_set(NRF_SPIM_Type * p_reg,
472*150812a8SEvalZero uint8_t const * p_buffer,
473*150812a8SEvalZero size_t length);
474*150812a8SEvalZero
475*150812a8SEvalZero /**
476*150812a8SEvalZero * @brief Function for setting the receive buffer.
477*150812a8SEvalZero *
478*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
479*150812a8SEvalZero * @param[in] p_buffer Pointer to the buffer for received data.
480*150812a8SEvalZero * @param[in] length Maximum number of data bytes to receive.
481*150812a8SEvalZero */
482*150812a8SEvalZero __STATIC_INLINE void nrf_spim_rx_buffer_set(NRF_SPIM_Type * p_reg,
483*150812a8SEvalZero uint8_t * p_buffer,
484*150812a8SEvalZero size_t length);
485*150812a8SEvalZero
486*150812a8SEvalZero /**
487*150812a8SEvalZero * @brief Function for setting the SPI configuration.
488*150812a8SEvalZero *
489*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
490*150812a8SEvalZero * @param[in] spi_mode SPI mode.
491*150812a8SEvalZero * @param[in] spi_bit_order SPI bit order.
492*150812a8SEvalZero */
493*150812a8SEvalZero __STATIC_INLINE void nrf_spim_configure(NRF_SPIM_Type * p_reg,
494*150812a8SEvalZero nrf_spim_mode_t spi_mode,
495*150812a8SEvalZero nrf_spim_bit_order_t spi_bit_order);
496*150812a8SEvalZero
497*150812a8SEvalZero /**
498*150812a8SEvalZero * @brief Function for setting the over-read character.
499*150812a8SEvalZero *
500*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
501*150812a8SEvalZero * @param[in] orc Over-read character that is clocked out in case of
502*150812a8SEvalZero * an over-read of the TXD buffer.
503*150812a8SEvalZero */
504*150812a8SEvalZero __STATIC_INLINE void nrf_spim_orc_set(NRF_SPIM_Type * p_reg,
505*150812a8SEvalZero uint8_t orc);
506*150812a8SEvalZero
507*150812a8SEvalZero /**
508*150812a8SEvalZero * @brief Function for enabling the TX list feature.
509*150812a8SEvalZero *
510*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
511*150812a8SEvalZero */
512*150812a8SEvalZero __STATIC_INLINE void nrf_spim_tx_list_enable(NRF_SPIM_Type * p_reg);
513*150812a8SEvalZero
514*150812a8SEvalZero /**
515*150812a8SEvalZero * @brief Function for disabling the TX list feature.
516*150812a8SEvalZero *
517*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
518*150812a8SEvalZero */
519*150812a8SEvalZero __STATIC_INLINE void nrf_spim_tx_list_disable(NRF_SPIM_Type * p_reg);
520*150812a8SEvalZero
521*150812a8SEvalZero /**
522*150812a8SEvalZero * @brief Function for enabling the RX list feature.
523*150812a8SEvalZero *
524*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
525*150812a8SEvalZero */
526*150812a8SEvalZero __STATIC_INLINE void nrf_spim_rx_list_enable(NRF_SPIM_Type * p_reg);
527*150812a8SEvalZero
528*150812a8SEvalZero /**
529*150812a8SEvalZero * @brief Function for disabling the RX list feature.
530*150812a8SEvalZero *
531*150812a8SEvalZero * @param[in] p_reg Pointer to the peripheral registers structure.
532*150812a8SEvalZero */
533*150812a8SEvalZero __STATIC_INLINE void nrf_spim_rx_list_disable(NRF_SPIM_Type * p_reg);
534*150812a8SEvalZero
535*150812a8SEvalZero #ifndef SUPPRESS_INLINE_IMPLEMENTATION
536*150812a8SEvalZero
nrf_spim_task_trigger(NRF_SPIM_Type * p_reg,nrf_spim_task_t spim_task)537*150812a8SEvalZero __STATIC_INLINE void nrf_spim_task_trigger(NRF_SPIM_Type * p_reg,
538*150812a8SEvalZero nrf_spim_task_t spim_task)
539*150812a8SEvalZero {
540*150812a8SEvalZero *((volatile uint32_t *)((uint8_t *)p_reg + (uint32_t)spim_task)) = 0x1UL;
541*150812a8SEvalZero }
542*150812a8SEvalZero
nrf_spim_task_address_get(NRF_SPIM_Type * p_reg,nrf_spim_task_t spim_task)543*150812a8SEvalZero __STATIC_INLINE uint32_t nrf_spim_task_address_get(NRF_SPIM_Type * p_reg,
544*150812a8SEvalZero nrf_spim_task_t spim_task)
545*150812a8SEvalZero {
546*150812a8SEvalZero return (uint32_t)((uint8_t *)p_reg + (uint32_t)spim_task);
547*150812a8SEvalZero }
548*150812a8SEvalZero
nrf_spim_event_clear(NRF_SPIM_Type * p_reg,nrf_spim_event_t spim_event)549*150812a8SEvalZero __STATIC_INLINE void nrf_spim_event_clear(NRF_SPIM_Type * p_reg,
550*150812a8SEvalZero nrf_spim_event_t spim_event)
551*150812a8SEvalZero {
552*150812a8SEvalZero *((volatile uint32_t *)((uint8_t *)p_reg + (uint32_t)spim_event)) = 0x0UL;
553*150812a8SEvalZero #if __CORTEX_M == 0x04
554*150812a8SEvalZero volatile uint32_t dummy = *((volatile uint32_t *)((uint8_t *)p_reg + (uint32_t)spim_event));
555*150812a8SEvalZero (void)dummy;
556*150812a8SEvalZero #endif
557*150812a8SEvalZero }
558*150812a8SEvalZero
nrf_spim_event_check(NRF_SPIM_Type * p_reg,nrf_spim_event_t spim_event)559*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_event_check(NRF_SPIM_Type * p_reg,
560*150812a8SEvalZero nrf_spim_event_t spim_event)
561*150812a8SEvalZero {
562*150812a8SEvalZero return (bool)*(volatile uint32_t *)((uint8_t *)p_reg + (uint32_t)spim_event);
563*150812a8SEvalZero }
564*150812a8SEvalZero
nrf_spim_event_address_get(NRF_SPIM_Type * p_reg,nrf_spim_event_t spim_event)565*150812a8SEvalZero __STATIC_INLINE uint32_t nrf_spim_event_address_get(NRF_SPIM_Type * p_reg,
566*150812a8SEvalZero nrf_spim_event_t spim_event)
567*150812a8SEvalZero {
568*150812a8SEvalZero return (uint32_t)((uint8_t *)p_reg + (uint32_t)spim_event);
569*150812a8SEvalZero }
570*150812a8SEvalZero
nrf_spim_shorts_enable(NRF_SPIM_Type * p_reg,uint32_t spim_shorts_mask)571*150812a8SEvalZero __STATIC_INLINE void nrf_spim_shorts_enable(NRF_SPIM_Type * p_reg,
572*150812a8SEvalZero uint32_t spim_shorts_mask)
573*150812a8SEvalZero {
574*150812a8SEvalZero p_reg->SHORTS |= spim_shorts_mask;
575*150812a8SEvalZero }
576*150812a8SEvalZero
nrf_spim_shorts_disable(NRF_SPIM_Type * p_reg,uint32_t spim_shorts_mask)577*150812a8SEvalZero __STATIC_INLINE void nrf_spim_shorts_disable(NRF_SPIM_Type * p_reg,
578*150812a8SEvalZero uint32_t spim_shorts_mask)
579*150812a8SEvalZero {
580*150812a8SEvalZero p_reg->SHORTS &= ~(spim_shorts_mask);
581*150812a8SEvalZero }
582*150812a8SEvalZero
nrf_spim_shorts_get(NRF_SPIM_Type * p_reg)583*150812a8SEvalZero __STATIC_INLINE uint32_t nrf_spim_shorts_get(NRF_SPIM_Type * p_reg)
584*150812a8SEvalZero {
585*150812a8SEvalZero return p_reg->SHORTS;
586*150812a8SEvalZero }
587*150812a8SEvalZero
nrf_spim_int_enable(NRF_SPIM_Type * p_reg,uint32_t spim_int_mask)588*150812a8SEvalZero __STATIC_INLINE void nrf_spim_int_enable(NRF_SPIM_Type * p_reg,
589*150812a8SEvalZero uint32_t spim_int_mask)
590*150812a8SEvalZero {
591*150812a8SEvalZero p_reg->INTENSET = spim_int_mask;
592*150812a8SEvalZero }
593*150812a8SEvalZero
nrf_spim_int_disable(NRF_SPIM_Type * p_reg,uint32_t spim_int_mask)594*150812a8SEvalZero __STATIC_INLINE void nrf_spim_int_disable(NRF_SPIM_Type * p_reg,
595*150812a8SEvalZero uint32_t spim_int_mask)
596*150812a8SEvalZero {
597*150812a8SEvalZero p_reg->INTENCLR = spim_int_mask;
598*150812a8SEvalZero }
599*150812a8SEvalZero
nrf_spim_int_enable_check(NRF_SPIM_Type * p_reg,nrf_spim_int_mask_t spim_int)600*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_int_enable_check(NRF_SPIM_Type * p_reg,
601*150812a8SEvalZero nrf_spim_int_mask_t spim_int)
602*150812a8SEvalZero {
603*150812a8SEvalZero return (bool)(p_reg->INTENSET & spim_int);
604*150812a8SEvalZero }
605*150812a8SEvalZero
606*150812a8SEvalZero #if defined(DPPI_PRESENT)
nrf_spim_subscribe_set(NRF_SPIM_Type * p_reg,nrf_spim_task_t task,uint8_t channel)607*150812a8SEvalZero __STATIC_INLINE void nrf_spim_subscribe_set(NRF_SPIM_Type * p_reg,
608*150812a8SEvalZero nrf_spim_task_t task,
609*150812a8SEvalZero uint8_t channel)
610*150812a8SEvalZero {
611*150812a8SEvalZero *((volatile uint32_t *) ((uint8_t *) p_reg + (uint32_t) task + 0x80uL)) =
612*150812a8SEvalZero ((uint32_t)channel | SPIM_SUBSCRIBE_START_EN_Msk);
613*150812a8SEvalZero }
614*150812a8SEvalZero
nrf_spim_subscribe_clear(NRF_SPIM_Type * p_reg,nrf_spim_task_t task)615*150812a8SEvalZero __STATIC_INLINE void nrf_spim_subscribe_clear(NRF_SPIM_Type * p_reg,
616*150812a8SEvalZero nrf_spim_task_t task)
617*150812a8SEvalZero {
618*150812a8SEvalZero *((volatile uint32_t *) ((uint8_t *) p_reg + (uint32_t) task + 0x80uL)) = 0;
619*150812a8SEvalZero }
620*150812a8SEvalZero
nrf_spim_publish_set(NRF_SPIM_Type * p_reg,nrf_spim_event_t event,uint8_t channel)621*150812a8SEvalZero __STATIC_INLINE void nrf_spim_publish_set(NRF_SPIM_Type * p_reg,
622*150812a8SEvalZero nrf_spim_event_t event,
623*150812a8SEvalZero uint8_t channel)
624*150812a8SEvalZero {
625*150812a8SEvalZero *((volatile uint32_t *) ((uint8_t *) p_reg + (uint32_t) event + 0x80uL)) =
626*150812a8SEvalZero ((uint32_t)channel | SPIM_PUBLISH_STARTED_EN_Msk);
627*150812a8SEvalZero }
628*150812a8SEvalZero
nrf_spim_publish_clear(NRF_SPIM_Type * p_reg,nrf_spim_event_t event)629*150812a8SEvalZero __STATIC_INLINE void nrf_spim_publish_clear(NRF_SPIM_Type * p_reg,
630*150812a8SEvalZero nrf_spim_event_t event)
631*150812a8SEvalZero {
632*150812a8SEvalZero *((volatile uint32_t *) ((uint8_t *) p_reg + (uint32_t) event + 0x80uL)) = 0;
633*150812a8SEvalZero }
634*150812a8SEvalZero #endif // defined(DPPI_PRESENT)
635*150812a8SEvalZero
nrf_spim_enable(NRF_SPIM_Type * p_reg)636*150812a8SEvalZero __STATIC_INLINE void nrf_spim_enable(NRF_SPIM_Type * p_reg)
637*150812a8SEvalZero {
638*150812a8SEvalZero p_reg->ENABLE = (SPIM_ENABLE_ENABLE_Enabled << SPIM_ENABLE_ENABLE_Pos);
639*150812a8SEvalZero }
640*150812a8SEvalZero
nrf_spim_disable(NRF_SPIM_Type * p_reg)641*150812a8SEvalZero __STATIC_INLINE void nrf_spim_disable(NRF_SPIM_Type * p_reg)
642*150812a8SEvalZero {
643*150812a8SEvalZero p_reg->ENABLE = (SPIM_ENABLE_ENABLE_Disabled << SPIM_ENABLE_ENABLE_Pos);
644*150812a8SEvalZero }
645*150812a8SEvalZero
nrf_spim_pins_set(NRF_SPIM_Type * p_reg,uint32_t sck_pin,uint32_t mosi_pin,uint32_t miso_pin)646*150812a8SEvalZero __STATIC_INLINE void nrf_spim_pins_set(NRF_SPIM_Type * p_reg,
647*150812a8SEvalZero uint32_t sck_pin,
648*150812a8SEvalZero uint32_t mosi_pin,
649*150812a8SEvalZero uint32_t miso_pin)
650*150812a8SEvalZero {
651*150812a8SEvalZero p_reg->PSEL.SCK = sck_pin;
652*150812a8SEvalZero p_reg->PSEL.MOSI = mosi_pin;
653*150812a8SEvalZero p_reg->PSEL.MISO = miso_pin;
654*150812a8SEvalZero }
655*150812a8SEvalZero
656*150812a8SEvalZero #if (NRF_SPIM_HW_CSN_PRESENT)
nrf_spim_csn_configure(NRF_SPIM_Type * p_reg,uint32_t pin,nrf_spim_csn_pol_t polarity,uint32_t duration)657*150812a8SEvalZero __STATIC_INLINE void nrf_spim_csn_configure(NRF_SPIM_Type * p_reg,
658*150812a8SEvalZero uint32_t pin,
659*150812a8SEvalZero nrf_spim_csn_pol_t polarity,
660*150812a8SEvalZero uint32_t duration)
661*150812a8SEvalZero {
662*150812a8SEvalZero p_reg->PSEL.CSN = pin;
663*150812a8SEvalZero p_reg->CSNPOL = polarity;
664*150812a8SEvalZero p_reg->IFTIMING.CSNDUR = duration;
665*150812a8SEvalZero }
666*150812a8SEvalZero #endif // defined(NRF_SPIM_HW_CSN_PRESENT)
667*150812a8SEvalZero
668*150812a8SEvalZero #if defined(SPIM_PSELDCX_CONNECT_Msk)
nrf_spim_dcx_pin_set(NRF_SPIM_Type * p_reg,uint32_t dcx_pin)669*150812a8SEvalZero __STATIC_INLINE void nrf_spim_dcx_pin_set(NRF_SPIM_Type * p_reg,
670*150812a8SEvalZero uint32_t dcx_pin)
671*150812a8SEvalZero {
672*150812a8SEvalZero p_reg->PSELDCX = dcx_pin;
673*150812a8SEvalZero }
674*150812a8SEvalZero
nrf_spim_dcx_cnt_set(NRF_SPIM_Type * p_reg,uint32_t dcx_cnt)675*150812a8SEvalZero __STATIC_INLINE void nrf_spim_dcx_cnt_set(NRF_SPIM_Type * p_reg,
676*150812a8SEvalZero uint32_t dcx_cnt)
677*150812a8SEvalZero {
678*150812a8SEvalZero p_reg->DCXCNT = dcx_cnt;
679*150812a8SEvalZero }
680*150812a8SEvalZero #endif // defined(SPIM_PSELDCX_CONNECT_Msk)
681*150812a8SEvalZero
682*150812a8SEvalZero #if defined(SPIM_IFTIMING_RXDELAY_RXDELAY_Msk)
nrf_spim_iftiming_set(NRF_SPIM_Type * p_reg,uint32_t rxdelay)683*150812a8SEvalZero __STATIC_INLINE void nrf_spim_iftiming_set(NRF_SPIM_Type * p_reg,
684*150812a8SEvalZero uint32_t rxdelay)
685*150812a8SEvalZero {
686*150812a8SEvalZero p_reg->IFTIMING.RXDELAY = rxdelay;
687*150812a8SEvalZero }
688*150812a8SEvalZero #endif // defined(SPIM_IFTIMING_RXDELAY_RXDELAY_Msk)
689*150812a8SEvalZero
690*150812a8SEvalZero #if defined(SPIM_STALLSTAT_RX_Msk)
nrf_spim_stallstat_rx_clear(NRF_SPIM_Type * p_reg)691*150812a8SEvalZero __STATIC_INLINE void nrf_spim_stallstat_rx_clear(NRF_SPIM_Type * p_reg)
692*150812a8SEvalZero {
693*150812a8SEvalZero p_reg->STALLSTAT &= ~(SPIM_STALLSTAT_RX_Msk);
694*150812a8SEvalZero }
695*150812a8SEvalZero
nrf_spim_stallstat_rx_get(NRF_SPIM_Type * p_reg)696*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_stallstat_rx_get(NRF_SPIM_Type * p_reg)
697*150812a8SEvalZero {
698*150812a8SEvalZero return (p_reg->STALLSTAT & SPIM_STALLSTAT_RX_Msk) != 0;
699*150812a8SEvalZero }
700*150812a8SEvalZero #endif // defined(SPIM_STALLSTAT_RX_Msk)
701*150812a8SEvalZero
702*150812a8SEvalZero #if defined(SPIM_STALLSTAT_TX_Msk)
nrf_spim_stallstat_tx_clear(NRF_SPIM_Type * p_reg)703*150812a8SEvalZero __STATIC_INLINE void nrf_spim_stallstat_tx_clear(NRF_SPIM_Type * p_reg)
704*150812a8SEvalZero {
705*150812a8SEvalZero p_reg->STALLSTAT &= ~(SPIM_STALLSTAT_TX_Msk);
706*150812a8SEvalZero }
707*150812a8SEvalZero
nrf_spim_stallstat_tx_get(NRF_SPIM_Type * p_reg)708*150812a8SEvalZero __STATIC_INLINE bool nrf_spim_stallstat_tx_get(NRF_SPIM_Type * p_reg)
709*150812a8SEvalZero {
710*150812a8SEvalZero return (p_reg->STALLSTAT & SPIM_STALLSTAT_TX_Msk) != 0;
711*150812a8SEvalZero }
712*150812a8SEvalZero #endif // defined(SPIM_STALLSTAT_TX_Msk)
713*150812a8SEvalZero
nrf_spim_frequency_set(NRF_SPIM_Type * p_reg,nrf_spim_frequency_t frequency)714*150812a8SEvalZero __STATIC_INLINE void nrf_spim_frequency_set(NRF_SPIM_Type * p_reg,
715*150812a8SEvalZero nrf_spim_frequency_t frequency)
716*150812a8SEvalZero {
717*150812a8SEvalZero p_reg->FREQUENCY = frequency;
718*150812a8SEvalZero }
719*150812a8SEvalZero
nrf_spim_tx_buffer_set(NRF_SPIM_Type * p_reg,uint8_t const * p_buffer,size_t length)720*150812a8SEvalZero __STATIC_INLINE void nrf_spim_tx_buffer_set(NRF_SPIM_Type * p_reg,
721*150812a8SEvalZero uint8_t const * p_buffer,
722*150812a8SEvalZero size_t length)
723*150812a8SEvalZero {
724*150812a8SEvalZero p_reg->TXD.PTR = (uint32_t)p_buffer;
725*150812a8SEvalZero p_reg->TXD.MAXCNT = length;
726*150812a8SEvalZero }
727*150812a8SEvalZero
nrf_spim_rx_buffer_set(NRF_SPIM_Type * p_reg,uint8_t * p_buffer,size_t length)728*150812a8SEvalZero __STATIC_INLINE void nrf_spim_rx_buffer_set(NRF_SPIM_Type * p_reg,
729*150812a8SEvalZero uint8_t * p_buffer,
730*150812a8SEvalZero size_t length)
731*150812a8SEvalZero {
732*150812a8SEvalZero p_reg->RXD.PTR = (uint32_t)p_buffer;
733*150812a8SEvalZero p_reg->RXD.MAXCNT = length;
734*150812a8SEvalZero }
735*150812a8SEvalZero
nrf_spim_configure(NRF_SPIM_Type * p_reg,nrf_spim_mode_t spi_mode,nrf_spim_bit_order_t spi_bit_order)736*150812a8SEvalZero __STATIC_INLINE void nrf_spim_configure(NRF_SPIM_Type * p_reg,
737*150812a8SEvalZero nrf_spim_mode_t spi_mode,
738*150812a8SEvalZero nrf_spim_bit_order_t spi_bit_order)
739*150812a8SEvalZero {
740*150812a8SEvalZero uint32_t config = (spi_bit_order == NRF_SPIM_BIT_ORDER_MSB_FIRST ?
741*150812a8SEvalZero SPIM_CONFIG_ORDER_MsbFirst : SPIM_CONFIG_ORDER_LsbFirst);
742*150812a8SEvalZero switch (spi_mode)
743*150812a8SEvalZero {
744*150812a8SEvalZero default:
745*150812a8SEvalZero case NRF_SPIM_MODE_0:
746*150812a8SEvalZero config |= (SPIM_CONFIG_CPOL_ActiveHigh << SPIM_CONFIG_CPOL_Pos) |
747*150812a8SEvalZero (SPIM_CONFIG_CPHA_Leading << SPIM_CONFIG_CPHA_Pos);
748*150812a8SEvalZero break;
749*150812a8SEvalZero
750*150812a8SEvalZero case NRF_SPIM_MODE_1:
751*150812a8SEvalZero config |= (SPIM_CONFIG_CPOL_ActiveHigh << SPIM_CONFIG_CPOL_Pos) |
752*150812a8SEvalZero (SPIM_CONFIG_CPHA_Trailing << SPIM_CONFIG_CPHA_Pos);
753*150812a8SEvalZero break;
754*150812a8SEvalZero
755*150812a8SEvalZero case NRF_SPIM_MODE_2:
756*150812a8SEvalZero config |= (SPIM_CONFIG_CPOL_ActiveLow << SPIM_CONFIG_CPOL_Pos) |
757*150812a8SEvalZero (SPIM_CONFIG_CPHA_Leading << SPIM_CONFIG_CPHA_Pos);
758*150812a8SEvalZero break;
759*150812a8SEvalZero
760*150812a8SEvalZero case NRF_SPIM_MODE_3:
761*150812a8SEvalZero config |= (SPIM_CONFIG_CPOL_ActiveLow << SPIM_CONFIG_CPOL_Pos) |
762*150812a8SEvalZero (SPIM_CONFIG_CPHA_Trailing << SPIM_CONFIG_CPHA_Pos);
763*150812a8SEvalZero break;
764*150812a8SEvalZero }
765*150812a8SEvalZero p_reg->CONFIG = config;
766*150812a8SEvalZero }
767*150812a8SEvalZero
nrf_spim_orc_set(NRF_SPIM_Type * p_reg,uint8_t orc)768*150812a8SEvalZero __STATIC_INLINE void nrf_spim_orc_set(NRF_SPIM_Type * p_reg,
769*150812a8SEvalZero uint8_t orc)
770*150812a8SEvalZero {
771*150812a8SEvalZero p_reg->ORC = orc;
772*150812a8SEvalZero }
773*150812a8SEvalZero
774*150812a8SEvalZero
nrf_spim_tx_list_enable(NRF_SPIM_Type * p_reg)775*150812a8SEvalZero __STATIC_INLINE void nrf_spim_tx_list_enable(NRF_SPIM_Type * p_reg)
776*150812a8SEvalZero {
777*150812a8SEvalZero p_reg->TXD.LIST = 1;
778*150812a8SEvalZero }
779*150812a8SEvalZero
nrf_spim_tx_list_disable(NRF_SPIM_Type * p_reg)780*150812a8SEvalZero __STATIC_INLINE void nrf_spim_tx_list_disable(NRF_SPIM_Type * p_reg)
781*150812a8SEvalZero {
782*150812a8SEvalZero p_reg->TXD.LIST = 0;
783*150812a8SEvalZero }
784*150812a8SEvalZero
nrf_spim_rx_list_enable(NRF_SPIM_Type * p_reg)785*150812a8SEvalZero __STATIC_INLINE void nrf_spim_rx_list_enable(NRF_SPIM_Type * p_reg)
786*150812a8SEvalZero {
787*150812a8SEvalZero p_reg->RXD.LIST = 1;
788*150812a8SEvalZero }
789*150812a8SEvalZero
nrf_spim_rx_list_disable(NRF_SPIM_Type * p_reg)790*150812a8SEvalZero __STATIC_INLINE void nrf_spim_rx_list_disable(NRF_SPIM_Type * p_reg)
791*150812a8SEvalZero {
792*150812a8SEvalZero p_reg->RXD.LIST = 0;
793*150812a8SEvalZero }
794*150812a8SEvalZero
795*150812a8SEvalZero #endif // SUPPRESS_INLINE_IMPLEMENTATION
796*150812a8SEvalZero
797*150812a8SEvalZero /** @} */
798*150812a8SEvalZero
799*150812a8SEvalZero #ifdef __cplusplus
800*150812a8SEvalZero }
801*150812a8SEvalZero #endif
802*150812a8SEvalZero
803*150812a8SEvalZero #endif // NRF_SPIM_H__
804