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mbed official / mbed-dev

mbed library sources. Supersedes mbed-src.

Dependents: Nucleo_Hello_Encoder BLE_iBeaconScan AM1805_DEMO DISCO-F429ZI_ExportTemplate1 ... more

targets/TARGET_NUVOTON/TARGET_NUC472/spi_api.c@149:156823d33999, 2016-10-28 (annotated)

Committer:: <>
Date:: Fri Oct 28 11:17:30 2016 +0100
Revision:: 149:156823d33999
Child:: 153:fa9ff456f731

This updates the lib to the mbed lib v128

NOTE: This release includes a restructuring of the file and directory locations and thus some

include paths in your code may need updating accordingly.

Who changed what in which revision?

User	Revision	Line number	New contents of line
<>	149:156823d33999	1	/* mbed Microcontroller Library
<>	149:156823d33999	2	* Copyright (c) 2015-2016 Nuvoton
<>	149:156823d33999	3	*
<>	149:156823d33999	4	* Licensed under the Apache License, Version 2.0 (the "License");
<>	149:156823d33999	5	* you may not use this file except in compliance with the License.
<>	149:156823d33999	6	* You may obtain a copy of the License at
<>	149:156823d33999	7	*
<>	149:156823d33999	8	* http://www.apache.org/licenses/LICENSE-2.0
<>	149:156823d33999	9	*
<>	149:156823d33999	10	* Unless required by applicable law or agreed to in writing, software
<>	149:156823d33999	11	* distributed under the License is distributed on an "AS IS" BASIS,
<>	149:156823d33999	12	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
<>	149:156823d33999	13	* See the License for the specific language governing permissions and
<>	149:156823d33999	14	* limitations under the License.
<>	149:156823d33999	15	*/
<>	149:156823d33999	16
<>	149:156823d33999	17	#include "spi_api.h"
<>	149:156823d33999	18
<>	149:156823d33999	19	#if DEVICE_SPI
<>	149:156823d33999	20
<>	149:156823d33999	21	#include "cmsis.h"
<>	149:156823d33999	22	#include "pinmap.h"
<>	149:156823d33999	23	#include "PeripheralPins.h"
<>	149:156823d33999	24	#include "nu_modutil.h"
<>	149:156823d33999	25	#include "nu_miscutil.h"
<>	149:156823d33999	26	#include "nu_bitutil.h"
<>	149:156823d33999	27
<>	149:156823d33999	28	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	29	#include "dma_api.h"
<>	149:156823d33999	30	#include "dma.h"
<>	149:156823d33999	31	#endif
<>	149:156823d33999	32
<>	149:156823d33999	33	#define NU_SPI_FRAME_MIN 8
<>	149:156823d33999	34	#define NU_SPI_FRAME_MAX 32
<>	149:156823d33999	35	#define NU_SPI_FIFO_DEPTH 8
<>	149:156823d33999	36
<>	149:156823d33999	37	struct nu_spi_var {
<>	149:156823d33999	38	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	39	uint8_t pdma_perp_tx;
<>	149:156823d33999	40	uint8_t pdma_perp_rx;
<>	149:156823d33999	41	#endif
<>	149:156823d33999	42	};
<>	149:156823d33999	43
<>	149:156823d33999	44	static struct nu_spi_var spi0_var = {
<>	149:156823d33999	45	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	46	.pdma_perp_tx = PDMA_SPI0_TX,
<>	149:156823d33999	47	.pdma_perp_rx = PDMA_SPI0_RX
<>	149:156823d33999	48	#endif
<>	149:156823d33999	49	};
<>	149:156823d33999	50	static struct nu_spi_var spi1_var = {
<>	149:156823d33999	51	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	52	.pdma_perp_tx = PDMA_SPI1_TX,
<>	149:156823d33999	53	.pdma_perp_rx = PDMA_SPI1_RX
<>	149:156823d33999	54	#endif
<>	149:156823d33999	55	};
<>	149:156823d33999	56	static struct nu_spi_var spi2_var = {
<>	149:156823d33999	57	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	58	.pdma_perp_tx = PDMA_SPI2_TX,
<>	149:156823d33999	59	.pdma_perp_rx = PDMA_SPI2_RX
<>	149:156823d33999	60	#endif
<>	149:156823d33999	61	};
<>	149:156823d33999	62	static struct nu_spi_var spi3_var = {
<>	149:156823d33999	63	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	64	.pdma_perp_tx = PDMA_SPI3_TX,
<>	149:156823d33999	65	.pdma_perp_rx = PDMA_SPI3_RX
<>	149:156823d33999	66	#endif
<>	149:156823d33999	67	};
<>	149:156823d33999	68
<>	149:156823d33999	69	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	70	static void spi_enable_vector_interrupt(spi_t *obj, uint32_t handler, uint8_t enable);
<>	149:156823d33999	71	static void spi_master_enable_interrupt(spi_t *obj, uint8_t enable);
<>	149:156823d33999	72	static uint32_t spi_master_write_asynch(spi_t *obj, uint32_t tx_limit);
<>	149:156823d33999	73	static uint32_t spi_master_read_asynch(spi_t *obj);
<>	149:156823d33999	74	static uint32_t spi_event_check(spi_t *obj);
<>	149:156823d33999	75	static void spi_enable_event(spi_t *obj, uint32_t event, uint8_t enable);
<>	149:156823d33999	76	static void spi_buffer_set(spi_t obj, const void tx, size_t tx_length, void *rx, size_t rx_length);
<>	149:156823d33999	77	static void spi_check_dma_usage(DMAUsage dma_usage, int dma_ch_tx, int *dma_ch_rx);
<>	149:156823d33999	78	static uint8_t spi_get_data_width(spi_t *obj);
<>	149:156823d33999	79	static int spi_is_tx_complete(spi_t *obj);
<>	149:156823d33999	80	static int spi_is_rx_complete(spi_t *obj);
<>	149:156823d33999	81	static int spi_writeable(spi_t * obj);
<>	149:156823d33999	82	static int spi_readable(spi_t * obj);
<>	149:156823d33999	83	static void spi_dma_handler_tx(uint32_t id, uint32_t event_dma);
<>	149:156823d33999	84	static void spi_dma_handler_rx(uint32_t id, uint32_t event_dma);
<>	149:156823d33999	85	#endif
<>	149:156823d33999	86
<>	149:156823d33999	87	static uint32_t spi_modinit_mask = 0;
<>	149:156823d33999	88
<>	149:156823d33999	89	static const struct nu_modinit_s spi_modinit_tab[] = {
<>	149:156823d33999	90	{SPI_0, SPI0_MODULE, 0, 0, SPI0_RST, SPI0_IRQn, &spi0_var},
<>	149:156823d33999	91	{SPI_1, SPI1_MODULE, 0, 0, SPI1_RST, SPI1_IRQn, &spi1_var},
<>	149:156823d33999	92	{SPI_2, SPI2_MODULE, 0, 0, SPI2_RST, SPI2_IRQn, &spi2_var},
<>	149:156823d33999	93	{SPI_3, SPI3_MODULE, 0, 0, SPI3_RST, SPI3_IRQn, &spi3_var},
<>	149:156823d33999	94
<>	149:156823d33999	95	{NC, 0, 0, 0, 0, (IRQn_Type) 0, NULL}
<>	149:156823d33999	96	};
<>	149:156823d33999	97
<>	149:156823d33999	98	void spi_init(spi_t *obj, PinName mosi, PinName miso, PinName sclk, PinName ssel) {
<>	149:156823d33999	99	// Determine which SPI_x the pins are used for
<>	149:156823d33999	100	uint32_t spi_mosi = pinmap_peripheral(mosi, PinMap_SPI_MOSI);
<>	149:156823d33999	101	uint32_t spi_miso = pinmap_peripheral(miso, PinMap_SPI_MISO);
<>	149:156823d33999	102	uint32_t spi_sclk = pinmap_peripheral(sclk, PinMap_SPI_SCLK);
<>	149:156823d33999	103	uint32_t spi_ssel = pinmap_peripheral(ssel, PinMap_SPI_SSEL);
<>	149:156823d33999	104	uint32_t spi_data = pinmap_merge(spi_mosi, spi_miso);
<>	149:156823d33999	105	uint32_t spi_cntl = pinmap_merge(spi_sclk, spi_ssel);
<>	149:156823d33999	106	obj->spi.spi = (SPIName) pinmap_merge(spi_data, spi_cntl);
<>	149:156823d33999	107	MBED_ASSERT((int)obj->spi.spi != NC);
<>	149:156823d33999	108
<>	149:156823d33999	109	const struct nu_modinit_s *modinit = get_modinit(obj->spi.spi, spi_modinit_tab);
<>	149:156823d33999	110	MBED_ASSERT(modinit != NULL);
<>	149:156823d33999	111	MBED_ASSERT(modinit->modname == obj->spi.spi);
<>	149:156823d33999	112
<>	149:156823d33999	113	// Reset this module
<>	149:156823d33999	114	SYS_ResetModule(modinit->rsetidx);
<>	149:156823d33999	115
<>	149:156823d33999	116	// Enable IP clock
<>	149:156823d33999	117	CLK_EnableModuleClock(modinit->clkidx);
<>	149:156823d33999	118
<>	149:156823d33999	119	//SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	120
<>	149:156823d33999	121	pinmap_pinout(mosi, PinMap_SPI_MOSI);
<>	149:156823d33999	122	pinmap_pinout(miso, PinMap_SPI_MISO);
<>	149:156823d33999	123	pinmap_pinout(sclk, PinMap_SPI_SCLK);
<>	149:156823d33999	124	pinmap_pinout(ssel, PinMap_SPI_SSEL);
<>	149:156823d33999	125
<>	149:156823d33999	126	obj->spi.pin_mosi = mosi;
<>	149:156823d33999	127	obj->spi.pin_miso = miso;
<>	149:156823d33999	128	obj->spi.pin_sclk = sclk;
<>	149:156823d33999	129	obj->spi.pin_ssel = ssel;
<>	149:156823d33999	130
<>	149:156823d33999	131	// Configure the SPI data format and frequency
<>	149:156823d33999	132	//spi_format(obj, 8, 0, SPI_MSB); // 8 bits, mode 0
<>	149:156823d33999	133	//spi_frequency(obj, 1000000);
<>	149:156823d33999	134
<>	149:156823d33999	135	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	136	obj->spi.dma_usage = DMA_USAGE_NEVER;
<>	149:156823d33999	137	obj->spi.event = 0;
<>	149:156823d33999	138	obj->spi.dma_chn_id_tx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	139	obj->spi.dma_chn_id_rx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	140	#endif
<>	149:156823d33999	141
<>	149:156823d33999	142	// Mark this module to be inited.
<>	149:156823d33999	143	int i = modinit - spi_modinit_tab;
<>	149:156823d33999	144	spi_modinit_mask \|= 1 << i;
<>	149:156823d33999	145	}
<>	149:156823d33999	146
<>	149:156823d33999	147	void spi_free(spi_t *obj)
<>	149:156823d33999	148	{
<>	149:156823d33999	149	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	150	if (obj->spi.dma_chn_id_tx != DMA_ERROR_OUT_OF_CHANNELS) {
<>	149:156823d33999	151	dma_channel_free(obj->spi.dma_chn_id_tx);
<>	149:156823d33999	152	obj->spi.dma_chn_id_tx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	153	}
<>	149:156823d33999	154	if (obj->spi.dma_chn_id_rx != DMA_ERROR_OUT_OF_CHANNELS) {
<>	149:156823d33999	155	dma_channel_free(obj->spi.dma_chn_id_rx);
<>	149:156823d33999	156	obj->spi.dma_chn_id_rx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	157	}
<>	149:156823d33999	158	#endif
<>	149:156823d33999	159
<>	149:156823d33999	160	SPI_Close((SPI_T *) NU_MODBASE(obj->spi.spi));
<>	149:156823d33999	161
<>	149:156823d33999	162	const struct nu_modinit_s *modinit = get_modinit(obj->spi.spi, spi_modinit_tab);
<>	149:156823d33999	163	MBED_ASSERT(modinit != NULL);
<>	149:156823d33999	164	MBED_ASSERT(modinit->modname == obj->spi.spi);
<>	149:156823d33999	165
<>	149:156823d33999	166	SPI_DisableInt(((SPI_T *) NU_MODBASE(obj->spi.spi)), (SPI_FIFO_RXOVIEN_MASK \| SPI_FIFO_RXTHIEN_MASK \| SPI_FIFO_TXTHIEN_MASK));
<>	149:156823d33999	167	NVIC_DisableIRQ(modinit->irq_n);
<>	149:156823d33999	168
<>	149:156823d33999	169	// Disable IP clock
<>	149:156823d33999	170	CLK_DisableModuleClock(modinit->clkidx);
<>	149:156823d33999	171
<>	149:156823d33999	172	//((struct nu_spi_var *) modinit->var)->obj = NULL;
<>	149:156823d33999	173
<>	149:156823d33999	174	// Mark this module to be deinited.
<>	149:156823d33999	175	int i = modinit - spi_modinit_tab;
<>	149:156823d33999	176	spi_modinit_mask &= ~(1 << i);
<>	149:156823d33999	177	}
<>	149:156823d33999	178	void spi_format(spi_t *obj, int bits, int mode, int slave)
<>	149:156823d33999	179	{
<>	149:156823d33999	180	MBED_ASSERT(bits >= NU_SPI_FRAME_MIN && bits <= NU_SPI_FRAME_MAX);
<>	149:156823d33999	181
<>	149:156823d33999	182	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	183
<>	149:156823d33999	184	// NOTE 1: All configurations should be ready before enabling SPI peripheral.
<>	149:156823d33999	185	// NOTE 2: Re-configuration is allowed only as SPI peripheral is idle.
<>	149:156823d33999	186	while (SPI_IS_BUSY(spi_base));
<>	149:156823d33999	187	SPI_DISABLE(spi_base);
<>	149:156823d33999	188
<>	149:156823d33999	189	SPI_Open(spi_base,
<>	149:156823d33999	190	slave ? SPI_SLAVE : SPI_MASTER,
<>	149:156823d33999	191	(mode == 0) ? SPI_MODE_0 : (mode == 1) ? SPI_MODE_1 : (mode == 2) ? SPI_MODE_2 : SPI_MODE_3,
<>	149:156823d33999	192	bits,
<>	149:156823d33999	193	SPI_GetBusClock(spi_base));
<>	149:156823d33999	194	// NOTE: Hardcode to be MSB first.
<>	149:156823d33999	195	SPI_SET_MSB_FIRST(spi_base);
<>	149:156823d33999	196
<>	149:156823d33999	197	if (! slave) {
<>	149:156823d33999	198	// Master
<>	149:156823d33999	199	if (obj->spi.pin_ssel != NC) {
<>	149:156823d33999	200	// Configure SS as low active.
<>	149:156823d33999	201	SPI_EnableAutoSS(spi_base, SPI_SS0, SPI_SS_ACTIVE_LOW);
<>	149:156823d33999	202	// NOTE: In NUC472 series, all SPI SS pins are SS0, so we can hardcode SS0 here.
<>	149:156823d33999	203	}
<>	149:156823d33999	204	else {
<>	149:156823d33999	205	SPI_DisableAutoSS(spi_base);
<>	149:156823d33999	206	}
<>	149:156823d33999	207	}
<>	149:156823d33999	208	else {
<>	149:156823d33999	209	// Slave
<>	149:156823d33999	210	// Configure SS as low active.
<>	149:156823d33999	211	spi_base->SSCTL &= ~SPI_SSCTL_SSACTPOL_Msk;
<>	149:156823d33999	212	// NOTE: SPI_SS0 is defined as the slave select input in Slave mode.
<>	149:156823d33999	213	}
<>	149:156823d33999	214	}
<>	149:156823d33999	215
<>	149:156823d33999	216	void spi_frequency(spi_t *obj, int hz)
<>	149:156823d33999	217	{
<>	149:156823d33999	218	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	219
<>	149:156823d33999	220	while (SPI_IS_BUSY(spi_base));
<>	149:156823d33999	221	SPI_DISABLE(spi_base);
<>	149:156823d33999	222
<>	149:156823d33999	223	SPI_SetBusClock((SPI_T *) NU_MODBASE(obj->spi.spi), hz);
<>	149:156823d33999	224	}
<>	149:156823d33999	225
<>	149:156823d33999	226
<>	149:156823d33999	227	int spi_master_write(spi_t *obj, int value)
<>	149:156823d33999	228	{
<>	149:156823d33999	229	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	230
<>	149:156823d33999	231	// NOTE: Data in receive FIFO can be read out via ICE.
<>	149:156823d33999	232	SPI_ENABLE(spi_base);
<>	149:156823d33999	233
<>	149:156823d33999	234	// Wait for tx buffer empty
<>	149:156823d33999	235	while(! spi_writeable(obj));
<>	149:156823d33999	236	SPI_WRITE_TX(spi_base, value);
<>	149:156823d33999	237
<>	149:156823d33999	238	// Wait for rx buffer full
<>	149:156823d33999	239	while (! spi_readable(obj));
<>	149:156823d33999	240	int value2 = SPI_READ_RX(spi_base);
<>	149:156823d33999	241
<>	149:156823d33999	242	SPI_DISABLE(spi_base);
<>	149:156823d33999	243
<>	149:156823d33999	244	return value2;
<>	149:156823d33999	245	}
<>	149:156823d33999	246
<>	149:156823d33999	247	#if DEVICE_SPISLAVE
<>	149:156823d33999	248	int spi_slave_receive(spi_t *obj)
<>	149:156823d33999	249	{
<>	149:156823d33999	250	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	251
<>	149:156823d33999	252	SPI_ENABLE(spi_base);
<>	149:156823d33999	253
<>	149:156823d33999	254	return spi_readable(obj);
<>	149:156823d33999	255	};
<>	149:156823d33999	256
<>	149:156823d33999	257	int spi_slave_read(spi_t *obj)
<>	149:156823d33999	258	{
<>	149:156823d33999	259	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	260
<>	149:156823d33999	261	SPI_ENABLE(spi_base);
<>	149:156823d33999	262
<>	149:156823d33999	263	// Wait for rx buffer full
<>	149:156823d33999	264	while (! spi_readable(obj));
<>	149:156823d33999	265	int value = SPI_READ_RX(spi_base);
<>	149:156823d33999	266	return value;
<>	149:156823d33999	267	}
<>	149:156823d33999	268
<>	149:156823d33999	269	void spi_slave_write(spi_t *obj, int value)
<>	149:156823d33999	270	{
<>	149:156823d33999	271	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	272
<>	149:156823d33999	273	SPI_ENABLE(spi_base);
<>	149:156823d33999	274
<>	149:156823d33999	275	// Wait for tx buffer empty
<>	149:156823d33999	276	while(! spi_writeable(obj));
<>	149:156823d33999	277	SPI_WRITE_TX(spi_base, value);
<>	149:156823d33999	278	}
<>	149:156823d33999	279	#endif
<>	149:156823d33999	280
<>	149:156823d33999	281	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	282	void spi_master_transfer(spi_t obj, const void tx, size_t tx_length, void *rx, size_t rx_length, uint8_t bit_width, uint32_t handler, uint32_t event, DMAUsage hint)
<>	149:156823d33999	283	{
<>	149:156823d33999	284	//MBED_ASSERT(bits >= NU_SPI_FRAME_MIN && bits <= NU_SPI_FRAME_MAX);
<>	149:156823d33999	285	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	286	SPI_SET_DATA_WIDTH(spi_base, bit_width);
<>	149:156823d33999	287
<>	149:156823d33999	288	obj->spi.dma_usage = hint;
<>	149:156823d33999	289	spi_check_dma_usage(&obj->spi.dma_usage, &obj->spi.dma_chn_id_tx, &obj->spi.dma_chn_id_rx);
<>	149:156823d33999	290	uint32_t data_width = spi_get_data_width(obj);
<>	149:156823d33999	291	// Conditions to go DMA way:
<>	149:156823d33999	292	// (1) No DMA support for non-8 multiple data width.
<>	149:156823d33999	293	// (2) tx length >= rx length. Otherwise, as tx DMA is done, no bus activity for remaining rx.
<>	149:156823d33999	294	if ((data_width % 8) \|\|
<>	149:156823d33999	295	(tx_length < rx_length)) {
<>	149:156823d33999	296	obj->spi.dma_usage = DMA_USAGE_NEVER;
<>	149:156823d33999	297	dma_channel_free(obj->spi.dma_chn_id_tx);
<>	149:156823d33999	298	obj->spi.dma_chn_id_tx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	299	dma_channel_free(obj->spi.dma_chn_id_rx);
<>	149:156823d33999	300	obj->spi.dma_chn_id_rx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	301	}
<>	149:156823d33999	302
<>	149:156823d33999	303	// SPI IRQ is necessary for both interrupt way and DMA way
<>	149:156823d33999	304	spi_enable_event(obj, event, 1);
<>	149:156823d33999	305	spi_buffer_set(obj, tx, tx_length, rx, rx_length);
<>	149:156823d33999	306
<>	149:156823d33999	307	SPI_ENABLE(spi_base);
<>	149:156823d33999	308
<>	149:156823d33999	309	if (obj->spi.dma_usage == DMA_USAGE_NEVER) {
<>	149:156823d33999	310	// Interrupt way
<>	149:156823d33999	311	spi_master_write_asynch(obj, NU_SPI_FIFO_DEPTH / 2);
<>	149:156823d33999	312	spi_enable_vector_interrupt(obj, handler, 1);
<>	149:156823d33999	313	spi_master_enable_interrupt(obj, 1);
<>	149:156823d33999	314	} else {
<>	149:156823d33999	315	// DMA way
<>	149:156823d33999	316	const struct nu_modinit_s *modinit = get_modinit(obj->spi.spi, spi_modinit_tab);
<>	149:156823d33999	317	MBED_ASSERT(modinit != NULL);
<>	149:156823d33999	318	MBED_ASSERT(modinit->modname == obj->spi.spi);
<>	149:156823d33999	319
<>	149:156823d33999	320	// Configure tx DMA
<>	149:156823d33999	321	PDMA->CHCTL \|= 1 << obj->spi.dma_chn_id_tx; // Enable this DMA channel
<>	149:156823d33999	322	PDMA_SetTransferMode(obj->spi.dma_chn_id_tx,
<>	149:156823d33999	323	((struct nu_spi_var *) modinit->var)->pdma_perp_tx, // Peripheral connected to this PDMA
<>	149:156823d33999	324	0, // Scatter-gather disabled
<>	149:156823d33999	325	0); // Scatter-gather descriptor address
<>	149:156823d33999	326	PDMA_SetTransferCnt(obj->spi.dma_chn_id_tx,
<>	149:156823d33999	327	(data_width == 8) ? PDMA_WIDTH_8 : (data_width == 16) ? PDMA_WIDTH_16 : PDMA_WIDTH_32,
<>	149:156823d33999	328	tx_length);
<>	149:156823d33999	329	PDMA_SetTransferAddr(obj->spi.dma_chn_id_tx,
<>	149:156823d33999	330	((uint32_t) tx) + (data_width / 8) * tx_length, // NOTE: End of source address
<>	149:156823d33999	331	PDMA_SAR_INC, // Source address incremental
<>	149:156823d33999	332	(uint32_t) &spi_base->TX, // Destination address
<>	149:156823d33999	333	PDMA_DAR_FIX); // Destination address fixed
<>	149:156823d33999	334	PDMA_SetBurstType(obj->spi.dma_chn_id_tx,
<>	149:156823d33999	335	PDMA_REQ_SINGLE, // Single mode
<>	149:156823d33999	336	0); // Burst size
<>	149:156823d33999	337	PDMA_EnableInt(obj->spi.dma_chn_id_tx,
<>	149:156823d33999	338	0); // Interrupt type. No use here
<>	149:156823d33999	339	// Register DMA event handler
<>	149:156823d33999	340	dma_set_handler(obj->spi.dma_chn_id_tx, (uint32_t) spi_dma_handler_tx, (uint32_t) obj, DMA_EVENT_ALL);
<>	149:156823d33999	341
<>	149:156823d33999	342	// Configure rx DMA
<>	149:156823d33999	343	PDMA->CHCTL \|= 1 << obj->spi.dma_chn_id_rx; // Enable this DMA channel
<>	149:156823d33999	344	PDMA_SetTransferMode(obj->spi.dma_chn_id_rx,
<>	149:156823d33999	345	((struct nu_spi_var *) modinit->var)->pdma_perp_rx, // Peripheral connected to this PDMA
<>	149:156823d33999	346	0, // Scatter-gather disabled
<>	149:156823d33999	347	0); // Scatter-gather descriptor address
<>	149:156823d33999	348	PDMA_SetTransferCnt(obj->spi.dma_chn_id_rx,
<>	149:156823d33999	349	(data_width == 8) ? PDMA_WIDTH_8 : (data_width == 16) ? PDMA_WIDTH_16 : PDMA_WIDTH_32,
<>	149:156823d33999	350	rx_length);
<>	149:156823d33999	351	PDMA_SetTransferAddr(obj->spi.dma_chn_id_rx,
<>	149:156823d33999	352	(uint32_t) &spi_base->RX, // Source address
<>	149:156823d33999	353	PDMA_SAR_FIX, // Source address fixed
<>	149:156823d33999	354	((uint32_t) rx) + (data_width / 8) * rx_length, // NOTE: End of destination address
<>	149:156823d33999	355	PDMA_DAR_INC); // Destination address incremental
<>	149:156823d33999	356	PDMA_SetBurstType(obj->spi.dma_chn_id_rx,
<>	149:156823d33999	357	PDMA_REQ_SINGLE, // Single mode
<>	149:156823d33999	358	0); // Burst size
<>	149:156823d33999	359	PDMA_EnableInt(obj->spi.dma_chn_id_rx,
<>	149:156823d33999	360	0); // Interrupt type. No use here
<>	149:156823d33999	361	// Register DMA event handler
<>	149:156823d33999	362	dma_set_handler(obj->spi.dma_chn_id_rx, (uint32_t) spi_dma_handler_rx, (uint32_t) obj, DMA_EVENT_ALL);
<>	149:156823d33999	363
<>	149:156823d33999	364	// Start tx/rx DMA transfer
<>	149:156823d33999	365	spi_enable_vector_interrupt(obj, handler, 1);
<>	149:156823d33999	366	// NOTE: It is safer to start rx DMA first and then tx DMA. Otherwise, receive FIFO is subject to overflow by tx DMA.
<>	149:156823d33999	367	SPI_TRIGGER_RX_PDMA(((SPI_T *) NU_MODBASE(obj->spi.spi)));
<>	149:156823d33999	368	SPI_TRIGGER_TX_PDMA(((SPI_T *) NU_MODBASE(obj->spi.spi)));
<>	149:156823d33999	369	spi_master_enable_interrupt(obj, 1);
<>	149:156823d33999	370	}
<>	149:156823d33999	371	}
<>	149:156823d33999	372
<>	149:156823d33999	373	/**
<>	149:156823d33999	374	* Abort an SPI transfer
<>	149:156823d33999	375	* This is a helper function for event handling. When any of the events listed occurs, the HAL will abort any ongoing
<>	149:156823d33999	376	* transfers
<>	149:156823d33999	377	* @param[in] obj The SPI peripheral to stop
<>	149:156823d33999	378	*/
<>	149:156823d33999	379	void spi_abort_asynch(spi_t *obj)
<>	149:156823d33999	380	{
<>	149:156823d33999	381	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	382
<>	149:156823d33999	383	if (obj->spi.dma_usage != DMA_USAGE_NEVER) {
<>	149:156823d33999	384	// Receive FIFO Overrun in case of tx length > rx length on DMA way
<>	149:156823d33999	385	if (spi_base->STATUS & SPI_STATUS_RXOVIF_Msk) {
<>	149:156823d33999	386	spi_base->STATUS = SPI_STATUS_RXOVIF_Msk;
<>	149:156823d33999	387	}
<>	149:156823d33999	388
<>	149:156823d33999	389	if (obj->spi.dma_chn_id_tx != DMA_ERROR_OUT_OF_CHANNELS) {
<>	149:156823d33999	390	PDMA_DisableInt(obj->spi.dma_chn_id_tx, 0);
<>	149:156823d33999	391	// FIXME: Next PDMA transfer will fail with PDMA_STOP() called. Cause is unknown.
<>	149:156823d33999	392	//PDMA_STOP(obj->spi.dma_chn_id_tx);
<>	149:156823d33999	393	PDMA->CHCTL &= ~(1 << obj->spi.dma_chn_id_tx);
<>	149:156823d33999	394	}
<>	149:156823d33999	395	SPI_DISABLE_TX_PDMA(((SPI_T *) NU_MODBASE(obj->spi.spi)));
<>	149:156823d33999	396
<>	149:156823d33999	397	if (obj->spi.dma_chn_id_rx != DMA_ERROR_OUT_OF_CHANNELS) {
<>	149:156823d33999	398	PDMA_DisableInt(obj->spi.dma_chn_id_rx, 0);
<>	149:156823d33999	399	// FIXME: Next PDMA transfer will fail with PDMA_STOP() called. Cause is unknown.
<>	149:156823d33999	400	//PDMA_STOP(obj->spi.dma_chn_id_rx);
<>	149:156823d33999	401	PDMA->CHCTL &= ~(1 << obj->spi.dma_chn_id_rx);
<>	149:156823d33999	402	}
<>	149:156823d33999	403	SPI_DISABLE_RX_PDMA(((SPI_T *) NU_MODBASE(obj->spi.spi)));
<>	149:156823d33999	404	}
<>	149:156823d33999	405
<>	149:156823d33999	406	// Necessary for both interrupt way and DMA way
<>	149:156823d33999	407	spi_enable_vector_interrupt(obj, 0, 0);
<>	149:156823d33999	408	spi_master_enable_interrupt(obj, 0);
<>	149:156823d33999	409
<>	149:156823d33999	410	// FIXME: SPI H/W may get out of state without the busy check.
<>	149:156823d33999	411	while (SPI_IS_BUSY(spi_base));
<>	149:156823d33999	412	SPI_DISABLE(spi_base);
<>	149:156823d33999	413
<>	149:156823d33999	414	SPI_ClearRxFIFO(spi_base);
<>	149:156823d33999	415	SPI_ClearTxFIFO(spi_base);
<>	149:156823d33999	416	}
<>	149:156823d33999	417
<>	149:156823d33999	418	/**
<>	149:156823d33999	419	* Handle the SPI interrupt
<>	149:156823d33999	420	* Read frames until the RX FIFO is empty. Write at most as many frames as were read. This way,
<>	149:156823d33999	421	* it is unlikely that the RX FIFO will overflow.
<>	149:156823d33999	422	* @param[in] obj The SPI peripheral that generated the interrupt
<>	149:156823d33999	423	* @return
<>	149:156823d33999	424	*/
<>	149:156823d33999	425	uint32_t spi_irq_handler_asynch(spi_t *obj)
<>	149:156823d33999	426	{
<>	149:156823d33999	427	// Check for SPI events
<>	149:156823d33999	428	uint32_t event = spi_event_check(obj);
<>	149:156823d33999	429	if (event) {
<>	149:156823d33999	430	spi_abort_asynch(obj);
<>	149:156823d33999	431	}
<>	149:156823d33999	432
<>	149:156823d33999	433	return (obj->spi.event & event) \| ((event & SPI_EVENT_COMPLETE) ? SPI_EVENT_INTERNAL_TRANSFER_COMPLETE : 0);
<>	149:156823d33999	434	}
<>	149:156823d33999	435
<>	149:156823d33999	436	uint8_t spi_active(spi_t *obj)
<>	149:156823d33999	437	{
<>	149:156823d33999	438	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	439	// FIXME
<>	149:156823d33999	440	/*
<>	149:156823d33999	441	if ((obj->rx_buff.buffer && obj->rx_buff.pos < obj->rx_buff.length)
<>	149:156823d33999	442	\|\| (obj->tx_buff.buffer && obj->tx_buff.pos < obj->tx_buff.length) ){
<>	149:156823d33999	443	return 1;
<>	149:156823d33999	444	} else {
<>	149:156823d33999	445	// interrupts are disabled, all transaction have been completed
<>	149:156823d33999	446	// TODO: checking rx fifo, it reports data eventhough RFDF is not set
<>	149:156823d33999	447	return DSPI_HAL_GetIntMode(obj->spi.address, kDspiRxFifoDrainRequest);
<>	149:156823d33999	448	}*/
<>	149:156823d33999	449
<>	149:156823d33999	450	//return SPI_IS_BUSY(spi_base);
<>	149:156823d33999	451	return (spi_base->CTL & SPI_CTL_SPIEN_Msk);
<>	149:156823d33999	452	}
<>	149:156823d33999	453
<>	149:156823d33999	454	int spi_allow_powerdown(void)
<>	149:156823d33999	455	{
<>	149:156823d33999	456	uint32_t modinit_mask = spi_modinit_mask;
<>	149:156823d33999	457	while (modinit_mask) {
<>	149:156823d33999	458	int spi_idx = nu_ctz(modinit_mask);
<>	149:156823d33999	459	const struct nu_modinit_s *modinit = spi_modinit_tab + spi_idx;
<>	149:156823d33999	460	if (modinit->modname != NC) {
<>	149:156823d33999	461	SPI_T spi_base = (SPI_T ) NU_MODBASE(modinit->modname);
<>	149:156823d33999	462	// Disallow entering power-down mode if SPI transfer is enabled.
<>	149:156823d33999	463	if (spi_base->CTL & SPI_CTL_SPIEN_Msk) {
<>	149:156823d33999	464	return 0;
<>	149:156823d33999	465	}
<>	149:156823d33999	466	}
<>	149:156823d33999	467	modinit_mask &= ~(1 << spi_idx);
<>	149:156823d33999	468	}
<>	149:156823d33999	469
<>	149:156823d33999	470	return 1;
<>	149:156823d33999	471	}
<>	149:156823d33999	472
<>	149:156823d33999	473	static int spi_writeable(spi_t * obj)
<>	149:156823d33999	474	{
<>	149:156823d33999	475	// Receive FIFO must not be full to avoid receive FIFO overflow on next transmit/receive
<>	149:156823d33999	476	//return (! SPI_GET_TX_FIFO_FULL_FLAG(((SPI_T ) NU_MODBASE(obj->spi.spi)))) && (SPI_GET_RX_FIFO_COUNT(((SPI_T ) NU_MODBASE(obj->spi.spi))) < NU_SPI_FIFO_DEPTH);
<>	149:156823d33999	477	return (! SPI_GET_TX_FIFO_FULL_FLAG(((SPI_T *) NU_MODBASE(obj->spi.spi))));
<>	149:156823d33999	478	}
<>	149:156823d33999	479
<>	149:156823d33999	480	static int spi_readable(spi_t * obj)
<>	149:156823d33999	481	{
<>	149:156823d33999	482	return ! SPI_GET_RX_FIFO_EMPTY_FLAG(((SPI_T *) NU_MODBASE(obj->spi.spi)));
<>	149:156823d33999	483	}
<>	149:156823d33999	484
<>	149:156823d33999	485	static void spi_enable_event(spi_t *obj, uint32_t event, uint8_t enable)
<>	149:156823d33999	486	{
<>	149:156823d33999	487	obj->spi.event &= ~SPI_EVENT_ALL;
<>	149:156823d33999	488	obj->spi.event \|= (event & SPI_EVENT_ALL);
<>	149:156823d33999	489	if (event & SPI_EVENT_RX_OVERFLOW) {
<>	149:156823d33999	490	SPI_EnableInt((SPI_T *) NU_MODBASE(obj->spi.spi), SPI_FIFO_RXOVIEN_MASK);
<>	149:156823d33999	491	}
<>	149:156823d33999	492	}
<>	149:156823d33999	493
<>	149:156823d33999	494	static void spi_enable_vector_interrupt(spi_t *obj, uint32_t handler, uint8_t enable)
<>	149:156823d33999	495	{
<>	149:156823d33999	496	const struct nu_modinit_s *modinit = get_modinit(obj->spi.spi, spi_modinit_tab);
<>	149:156823d33999	497	MBED_ASSERT(modinit != NULL);
<>	149:156823d33999	498	MBED_ASSERT(modinit->modname == obj->spi.spi);
<>	149:156823d33999	499
<>	149:156823d33999	500	if (enable) {
<>	149:156823d33999	501	NVIC_SetVector(modinit->irq_n, handler);
<>	149:156823d33999	502	NVIC_EnableIRQ(modinit->irq_n);
<>	149:156823d33999	503	}
<>	149:156823d33999	504	else {
<>	149:156823d33999	505	//NVIC_SetVector(modinit->irq_n, handler);
<>	149:156823d33999	506	NVIC_DisableIRQ(modinit->irq_n);
<>	149:156823d33999	507	}
<>	149:156823d33999	508	}
<>	149:156823d33999	509
<>	149:156823d33999	510	static void spi_master_enable_interrupt(spi_t *obj, uint8_t enable)
<>	149:156823d33999	511	{
<>	149:156823d33999	512	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	513
<>	149:156823d33999	514	if (enable) {
<>	149:156823d33999	515	SPI_SetFIFOThreshold(spi_base, 4, 4);
<>	149:156823d33999	516	//SPI_SET_SUSPEND_CYCLE(spi_base, 4);
<>	149:156823d33999	517	// Enable tx/rx FIFO threshold interrupt
<>	149:156823d33999	518	SPI_EnableInt(spi_base, SPI_FIFO_RXTHIEN_MASK \| SPI_FIFO_TXTHIEN_MASK);
<>	149:156823d33999	519	}
<>	149:156823d33999	520	else {
<>	149:156823d33999	521	SPI_DisableInt(spi_base, SPI_FIFO_RXTHIEN_MASK \| SPI_FIFO_TXTHIEN_MASK);
<>	149:156823d33999	522	}
<>	149:156823d33999	523	}
<>	149:156823d33999	524
<>	149:156823d33999	525	static uint32_t spi_event_check(spi_t *obj)
<>	149:156823d33999	526	{
<>	149:156823d33999	527	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	528	uint32_t event = 0;
<>	149:156823d33999	529
<>	149:156823d33999	530	if (obj->spi.dma_usage == DMA_USAGE_NEVER) {
<>	149:156823d33999	531	uint32_t n_rec = spi_master_read_asynch(obj);
<>	149:156823d33999	532	spi_master_write_asynch(obj, n_rec);
<>	149:156823d33999	533	}
<>	149:156823d33999	534
<>	149:156823d33999	535	if (spi_is_tx_complete(obj) && spi_is_rx_complete(obj)) {
<>	149:156823d33999	536	event \|= SPI_EVENT_COMPLETE;
<>	149:156823d33999	537	}
<>	149:156823d33999	538
<>	149:156823d33999	539	// Receive FIFO Overrun
<>	149:156823d33999	540	if (spi_base->STATUS & SPI_STATUS_RXOVIF_Msk) {
<>	149:156823d33999	541	spi_base->STATUS = SPI_STATUS_RXOVIF_Msk;
<>	149:156823d33999	542	// In case of tx length > rx length on DMA way
<>	149:156823d33999	543	if (obj->spi.dma_usage == DMA_USAGE_NEVER) {
<>	149:156823d33999	544	event \|= SPI_EVENT_RX_OVERFLOW;
<>	149:156823d33999	545	}
<>	149:156823d33999	546	}
<>	149:156823d33999	547
<>	149:156823d33999	548	// Receive Time-Out
<>	149:156823d33999	549	if (spi_base->STATUS & SPI_STATUS_RXTOIF_Msk) {
<>	149:156823d33999	550	spi_base->STATUS = SPI_STATUS_RXTOIF_Msk;
<>	149:156823d33999	551	//event \|= SPI_EVENT_ERROR;
<>	149:156823d33999	552	}
<>	149:156823d33999	553	// Transmit FIFO Under-Run
<>	149:156823d33999	554	if (spi_base->STATUS & SPI_STATUS_TXUFIF_Msk) {
<>	149:156823d33999	555	spi_base->STATUS = SPI_STATUS_TXUFIF_Msk;
<>	149:156823d33999	556	event \|= SPI_EVENT_ERROR;
<>	149:156823d33999	557	}
<>	149:156823d33999	558
<>	149:156823d33999	559	return event;
<>	149:156823d33999	560	}
<>	149:156823d33999	561
<>	149:156823d33999	562	/**
<>	149:156823d33999	563	* Send words from the SPI TX buffer until the send limit is reached or the TX FIFO is full
<>	149:156823d33999	564	* tx_limit is provided to ensure that the number of SPI frames (words) in flight can be managed.
<>	149:156823d33999	565	* @param[in] obj The SPI object on which to operate
<>	149:156823d33999	566	* @param[in] tx_limit The maximum number of words to send
<>	149:156823d33999	567	* @return The number of SPI words that have been transfered
<>	149:156823d33999	568	*/
<>	149:156823d33999	569	static uint32_t spi_master_write_asynch(spi_t *obj, uint32_t tx_limit)
<>	149:156823d33999	570	{
<>	149:156823d33999	571	uint32_t n_words = 0;
<>	149:156823d33999	572	uint32_t tx_rmn = obj->tx_buff.length - obj->tx_buff.pos;
<>	149:156823d33999	573	uint32_t rx_rmn = obj->rx_buff.length - obj->rx_buff.pos;
<>	149:156823d33999	574	uint32_t max_tx = NU_MAX(tx_rmn, rx_rmn);
<>	149:156823d33999	575	max_tx = NU_MIN(max_tx, tx_limit);
<>	149:156823d33999	576	uint8_t data_width = spi_get_data_width(obj);
<>	149:156823d33999	577	uint8_t bytes_per_word = (data_width + 7) / 8;
<>	149:156823d33999	578	uint8_t tx = (uint8_t )(obj->tx_buff.buffer) + bytes_per_word * obj->tx_buff.pos;
<>	149:156823d33999	579	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	580
<>	149:156823d33999	581	while ((n_words < max_tx) && spi_writeable(obj)) {
<>	149:156823d33999	582	if (spi_is_tx_complete(obj)) {
<>	149:156823d33999	583	// Transmit dummy as transmit buffer is empty
<>	149:156823d33999	584	SPI_WRITE_TX(spi_base, 0);
<>	149:156823d33999	585	}
<>	149:156823d33999	586	else {
<>	149:156823d33999	587	switch (bytes_per_word) {
<>	149:156823d33999	588	case 4:
<>	149:156823d33999	589	SPI_WRITE_TX(spi_base, nu_get32_le(tx));
<>	149:156823d33999	590	tx += 4;
<>	149:156823d33999	591	break;
<>	149:156823d33999	592	case 2:
<>	149:156823d33999	593	SPI_WRITE_TX(spi_base, nu_get16_le(tx));
<>	149:156823d33999	594	tx += 2;
<>	149:156823d33999	595	break;
<>	149:156823d33999	596	case 1:
<>	149:156823d33999	597	SPI_WRITE_TX(spi_base, ((uint8_t ) tx));
<>	149:156823d33999	598	tx += 1;
<>	149:156823d33999	599	break;
<>	149:156823d33999	600	}
<>	149:156823d33999	601
<>	149:156823d33999	602	obj->tx_buff.pos ++;
<>	149:156823d33999	603	}
<>	149:156823d33999	604	n_words ++;
<>	149:156823d33999	605	}
<>	149:156823d33999	606
<>	149:156823d33999	607	//Return the number of words that have been sent
<>	149:156823d33999	608	return n_words;
<>	149:156823d33999	609	}
<>	149:156823d33999	610
<>	149:156823d33999	611	/**
<>	149:156823d33999	612	* Read SPI words out of the RX FIFO
<>	149:156823d33999	613	* Continues reading words out of the RX FIFO until the following condition is met:
<>	149:156823d33999	614	* o There are no more words in the FIFO
<>	149:156823d33999	615	* OR BOTH OF:
<>	149:156823d33999	616	* o At least as many words as the TX buffer have been received
<>	149:156823d33999	617	* o At least as many words as the RX buffer have been received
<>	149:156823d33999	618	* This way, RX overflows are not generated when the TX buffer size exceeds the RX buffer size
<>	149:156823d33999	619	* @param[in] obj The SPI object on which to operate
<>	149:156823d33999	620	* @return Returns the number of words extracted from the RX FIFO
<>	149:156823d33999	621	*/
<>	149:156823d33999	622	static uint32_t spi_master_read_asynch(spi_t *obj)
<>	149:156823d33999	623	{
<>	149:156823d33999	624	uint32_t n_words = 0;
<>	149:156823d33999	625	uint32_t tx_rmn = obj->tx_buff.length - obj->tx_buff.pos;
<>	149:156823d33999	626	uint32_t rx_rmn = obj->rx_buff.length - obj->rx_buff.pos;
<>	149:156823d33999	627	uint32_t max_rx = NU_MAX(tx_rmn, rx_rmn);
<>	149:156823d33999	628	uint8_t data_width = spi_get_data_width(obj);
<>	149:156823d33999	629	uint8_t bytes_per_word = (data_width + 7) / 8;
<>	149:156823d33999	630	uint8_t rx = (uint8_t )(obj->rx_buff.buffer) + bytes_per_word * obj->rx_buff.pos;
<>	149:156823d33999	631	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	632
<>	149:156823d33999	633	while ((n_words < max_rx) && spi_readable(obj)) {
<>	149:156823d33999	634	if (spi_is_rx_complete(obj)) {
<>	149:156823d33999	635	// Disregard as receive buffer is full
<>	149:156823d33999	636	SPI_READ_RX(spi_base);
<>	149:156823d33999	637	}
<>	149:156823d33999	638	else {
<>	149:156823d33999	639	switch (bytes_per_word) {
<>	149:156823d33999	640	case 4: {
<>	149:156823d33999	641	uint32_t val = SPI_READ_RX(spi_base);
<>	149:156823d33999	642	nu_set32_le(rx, val);
<>	149:156823d33999	643	rx += 4;
<>	149:156823d33999	644	break;
<>	149:156823d33999	645	}
<>	149:156823d33999	646	case 2: {
<>	149:156823d33999	647	uint16_t val = SPI_READ_RX(spi_base);
<>	149:156823d33999	648	nu_set16_le(rx, val);
<>	149:156823d33999	649	rx += 2;
<>	149:156823d33999	650	break;
<>	149:156823d33999	651	}
<>	149:156823d33999	652	case 1:
<>	149:156823d33999	653	*rx ++ = SPI_READ_RX(spi_base);
<>	149:156823d33999	654	break;
<>	149:156823d33999	655	}
<>	149:156823d33999	656
<>	149:156823d33999	657	obj->rx_buff.pos ++;
<>	149:156823d33999	658	}
<>	149:156823d33999	659	n_words ++;
<>	149:156823d33999	660	}
<>	149:156823d33999	661
<>	149:156823d33999	662	// Return the number of words received
<>	149:156823d33999	663	return n_words;
<>	149:156823d33999	664	}
<>	149:156823d33999	665
<>	149:156823d33999	666	static void spi_buffer_set(spi_t obj, const void tx, size_t tx_length, void *rx, size_t rx_length)
<>	149:156823d33999	667	{
<>	149:156823d33999	668	obj->tx_buff.buffer = (void *) tx;
<>	149:156823d33999	669	obj->tx_buff.length = tx_length;
<>	149:156823d33999	670	obj->tx_buff.pos = 0;
<>	149:156823d33999	671	obj->tx_buff.width = spi_get_data_width(obj);
<>	149:156823d33999	672	obj->rx_buff.buffer = rx;
<>	149:156823d33999	673	obj->rx_buff.length = rx_length;
<>	149:156823d33999	674	obj->rx_buff.pos = 0;
<>	149:156823d33999	675	obj->rx_buff.width = spi_get_data_width(obj);
<>	149:156823d33999	676	}
<>	149:156823d33999	677
<>	149:156823d33999	678	static void spi_check_dma_usage(DMAUsage dma_usage, int dma_ch_tx, int *dma_ch_rx)
<>	149:156823d33999	679	{
<>	149:156823d33999	680	if (*dma_usage != DMA_USAGE_NEVER) {
<>	149:156823d33999	681	if (*dma_ch_tx == DMA_ERROR_OUT_OF_CHANNELS) {
<>	149:156823d33999	682	*dma_ch_tx = dma_channel_allocate(DMA_CAP_NONE);
<>	149:156823d33999	683	}
<>	149:156823d33999	684	if (*dma_ch_rx == DMA_ERROR_OUT_OF_CHANNELS) {
<>	149:156823d33999	685	*dma_ch_rx = dma_channel_allocate(DMA_CAP_NONE);
<>	149:156823d33999	686	}
<>	149:156823d33999	687
<>	149:156823d33999	688	if (dma_ch_tx == DMA_ERROR_OUT_OF_CHANNELS \|\| dma_ch_rx == DMA_ERROR_OUT_OF_CHANNELS) {
<>	149:156823d33999	689	*dma_usage = DMA_USAGE_NEVER;
<>	149:156823d33999	690	}
<>	149:156823d33999	691	}
<>	149:156823d33999	692
<>	149:156823d33999	693	if (*dma_usage == DMA_USAGE_NEVER) {
<>	149:156823d33999	694	dma_channel_free(*dma_ch_tx);
<>	149:156823d33999	695	*dma_ch_tx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	696	dma_channel_free(*dma_ch_rx);
<>	149:156823d33999	697	*dma_ch_rx = DMA_ERROR_OUT_OF_CHANNELS;
<>	149:156823d33999	698	}
<>	149:156823d33999	699	}
<>	149:156823d33999	700
<>	149:156823d33999	701	static uint8_t spi_get_data_width(spi_t *obj)
<>	149:156823d33999	702	{
<>	149:156823d33999	703	SPI_T spi_base = (SPI_T ) NU_MODBASE(obj->spi.spi);
<>	149:156823d33999	704
<>	149:156823d33999	705	return ((spi_base->CTL & SPI_CTL_DWIDTH_Msk) >> SPI_CTL_DWIDTH_Pos);
<>	149:156823d33999	706	}
<>	149:156823d33999	707
<>	149:156823d33999	708	static int spi_is_tx_complete(spi_t *obj)
<>	149:156823d33999	709	{
<>	149:156823d33999	710	// ???: Exclude tx fifo empty check due to no such interrupt on DMA way
<>	149:156823d33999	711	return (obj->tx_buff.pos == obj->tx_buff.length);
<>	149:156823d33999	712	//return (obj->tx_buff.pos == obj->tx_buff.length && SPI_GET_TX_FIFO_EMPTY_FLAG(((SPI_T *) NU_MODBASE(obj->spi.spi))));
<>	149:156823d33999	713	}
<>	149:156823d33999	714
<>	149:156823d33999	715	static int spi_is_rx_complete(spi_t *obj)
<>	149:156823d33999	716	{
<>	149:156823d33999	717	return (obj->rx_buff.pos == obj->rx_buff.length);
<>	149:156823d33999	718	}
<>	149:156823d33999	719
<>	149:156823d33999	720	static void spi_dma_handler_tx(uint32_t id, uint32_t event_dma)
<>	149:156823d33999	721	{
<>	149:156823d33999	722	spi_t obj = (spi_t ) id;
<>	149:156823d33999	723
<>	149:156823d33999	724	// FIXME: Pass this error to caller
<>	149:156823d33999	725	if (event_dma & DMA_EVENT_ABORT) {
<>	149:156823d33999	726	}
<>	149:156823d33999	727	// Expect SPI IRQ will catch this transfer done event
<>	149:156823d33999	728	if (event_dma & DMA_EVENT_TRANSFER_DONE) {
<>	149:156823d33999	729	obj->tx_buff.pos = obj->tx_buff.length;
<>	149:156823d33999	730	}
<>	149:156823d33999	731	// FIXME: Pass this error to caller
<>	149:156823d33999	732	if (event_dma & DMA_EVENT_TIMEOUT) {
<>	149:156823d33999	733	}
<>	149:156823d33999	734
<>	149:156823d33999	735	const struct nu_modinit_s *modinit = get_modinit(obj->spi.spi, spi_modinit_tab);
<>	149:156823d33999	736	MBED_ASSERT(modinit != NULL);
<>	149:156823d33999	737	MBED_ASSERT(modinit->modname == obj->spi.spi);
<>	149:156823d33999	738
<>	149:156823d33999	739	void (vec)(void) = (void ()(void)) NVIC_GetVector(modinit->irq_n);
<>	149:156823d33999	740	vec();
<>	149:156823d33999	741	}
<>	149:156823d33999	742
<>	149:156823d33999	743	static void spi_dma_handler_rx(uint32_t id, uint32_t event_dma)
<>	149:156823d33999	744	{
<>	149:156823d33999	745	spi_t obj = (spi_t ) id;
<>	149:156823d33999	746
<>	149:156823d33999	747	// FIXME: Pass this error to caller
<>	149:156823d33999	748	if (event_dma & DMA_EVENT_ABORT) {
<>	149:156823d33999	749	}
<>	149:156823d33999	750	// Expect SPI IRQ will catch this transfer done event
<>	149:156823d33999	751	if (event_dma & DMA_EVENT_TRANSFER_DONE) {
<>	149:156823d33999	752	obj->rx_buff.pos = obj->rx_buff.length;
<>	149:156823d33999	753	}
<>	149:156823d33999	754	// FIXME: Pass this error to caller
<>	149:156823d33999	755	if (event_dma & DMA_EVENT_TIMEOUT) {
<>	149:156823d33999	756	}
<>	149:156823d33999	757
<>	149:156823d33999	758	const struct nu_modinit_s *modinit = get_modinit(obj->spi.spi, spi_modinit_tab);
<>	149:156823d33999	759	MBED_ASSERT(modinit != NULL);
<>	149:156823d33999	760	MBED_ASSERT(modinit->modname == obj->spi.spi);
<>	149:156823d33999	761
<>	149:156823d33999	762	void (vec)(void) = (void ()(void)) NVIC_GetVector(modinit->irq_n);
<>	149:156823d33999	763	vec();
<>	149:156823d33999	764	}
<>	149:156823d33999	765
<>	149:156823d33999	766	#endif
<>	149:156823d33999	767
<>	149:156823d33999	768	#endif