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Marek Trojan / mbed-dev

mbed library sources. Supersedes mbed-src.

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targets/TARGET_Maxim/TARGET_MAX32620/spi_api.c@149:156823d33999, 2016-10-28 (annotated)

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

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	/*******************************************************************************
<>	149:156823d33999	2	* Copyright (C) 2016 Maxim Integrated Products, Inc., All Rights Reserved.
<>	149:156823d33999	3	*
<>	149:156823d33999	4	* Permission is hereby granted, free of charge, to any person obtaining a
<>	149:156823d33999	5	* copy of this software and associated documentation files (the "Software"),
<>	149:156823d33999	6	* to deal in the Software without restriction, including without limitation
<>	149:156823d33999	7	* the rights to use, copy, modify, merge, publish, distribute, sublicense,
<>	149:156823d33999	8	* and/or sell copies of the Software, and to permit persons to whom the
<>	149:156823d33999	9	* Software is furnished to do so, subject to the following conditions:
<>	149:156823d33999	10	*
<>	149:156823d33999	11	* The above copyright notice and this permission notice shall be included
<>	149:156823d33999	12	* in all copies or substantial portions of the Software.
<>	149:156823d33999	13	*
<>	149:156823d33999	14	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
<>	149:156823d33999	15	* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
<>	149:156823d33999	16	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
<>	149:156823d33999	17	* IN NO EVENT SHALL MAXIM INTEGRATED BE LIABLE FOR ANY CLAIM, DAMAGES
<>	149:156823d33999	18	* OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
<>	149:156823d33999	19	* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
<>	149:156823d33999	20	* OTHER DEALINGS IN THE SOFTWARE.
<>	149:156823d33999	21	*
<>	149:156823d33999	22	* Except as contained in this notice, the name of Maxim Integrated
<>	149:156823d33999	23	* Products, Inc. shall not be used except as stated in the Maxim Integrated
<>	149:156823d33999	24	* Products, Inc. Branding Policy.
<>	149:156823d33999	25	*
<>	149:156823d33999	26	* The mere transfer of this software does not imply any licenses
<>	149:156823d33999	27	* of trade secrets, proprietary technology, copyrights, patents,
<>	149:156823d33999	28	* trademarks, maskwork rights, or any other form of intellectual
<>	149:156823d33999	29	* property whatsoever. Maxim Integrated Products, Inc. retains all
<>	149:156823d33999	30	* ownership rights.
<>	149:156823d33999	31	*******************************************************************************
<>	149:156823d33999	32	*/
<>	149:156823d33999	33
<>	149:156823d33999	34	#include <string.h>
<>	149:156823d33999	35	#include "mbed_assert.h"
<>	149:156823d33999	36	#include "cmsis.h"
<>	149:156823d33999	37	#include "spi_api.h"
<>	149:156823d33999	38	#include "spi_multi_api.h"
<>	149:156823d33999	39	#include "pinmap.h"
<>	149:156823d33999	40	#include "ioman_regs.h"
<>	149:156823d33999	41	#include "clkman_regs.h"
<>	149:156823d33999	42	#include "PeripheralPins.h"
<>	149:156823d33999	43
<>	149:156823d33999	44	#define DEFAULT_CHAR 8
<>	149:156823d33999	45	#define DEFAULT_MODE 0
<>	149:156823d33999	46	#define DEFAULT_FREQ 1000000
<>	149:156823d33999	47
<>	149:156823d33999	48	// BYTE maximums for FIFO and page writes; FIFO depth spec'd as 16-bit words
<>	149:156823d33999	49	#define SPI_MAX_BYTE_LEN (MXC_CFG_SPI_FIFO_DEPTH * 2)
<>	149:156823d33999	50	#define SPI_MAX_PAGE_LEN (MXC_CFG_SPI_FIFO_DEPTH * 2)
<>	149:156823d33999	51
<>	149:156823d33999	52	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	53	// Instance references for async transactions
<>	149:156823d33999	54	static struct spi_s *state[MXC_CFG_SPI_INSTANCES] = {NULL};
<>	149:156823d33999	55	#endif
<>	149:156823d33999	56
<>	149:156823d33999	57	//******************************************************************************
<>	149:156823d33999	58	void spi_init(spi_t *obj, PinName mosi, PinName miso, PinName sclk, PinName ssel)
<>	149:156823d33999	59	{
<>	149:156823d33999	60	// Make sure pins are pointing to the same SPI instance
<>	149:156823d33999	61	SPIName spi_mosi = (SPIName)pinmap_peripheral(mosi, PinMap_SPI_MOSI);
<>	149:156823d33999	62	SPIName spi_miso = (SPIName)pinmap_peripheral(miso, PinMap_SPI_MISO);
<>	149:156823d33999	63	SPIName spi_sclk = (SPIName)pinmap_peripheral(sclk, PinMap_SPI_SCLK);
<>	149:156823d33999	64	SPIName spi_ssel = (SPIName)pinmap_peripheral(ssel, PinMap_SPI_SSEL);
<>	149:156823d33999	65
<>	149:156823d33999	66	SPIName spi_data = (SPIName)pinmap_merge(spi_mosi, spi_miso);
<>	149:156823d33999	67	SPIName spi_cntl;
<>	149:156823d33999	68
<>	149:156823d33999	69	// Give the application the option to manually control Slave Select
<>	149:156823d33999	70	if ((SPIName)spi_ssel != (SPIName)NC) {
<>	149:156823d33999	71	spi_cntl = (SPIName)pinmap_merge(spi_sclk, spi_ssel);
<>	149:156823d33999	72	// Slave select is currently limited to slave select zero. If others are
<>	149:156823d33999	73	// to be supported a function to map PinName to a value suitable for use
<>	149:156823d33999	74	// in mstr_cfg.slave_sel will be required.
<>	149:156823d33999	75	obj->spi.ssel = 0;
<>	149:156823d33999	76	} else {
<>	149:156823d33999	77	spi_cntl = spi_sclk;
<>	149:156823d33999	78	obj->spi.ssel = -1;
<>	149:156823d33999	79	}
<>	149:156823d33999	80
<>	149:156823d33999	81	SPIName spi = (SPIName)pinmap_merge(spi_data, spi_cntl);
<>	149:156823d33999	82
<>	149:156823d33999	83	MBED_ASSERT((SPIName)spi != (SPIName)NC);
<>	149:156823d33999	84
<>	149:156823d33999	85	// Set the obj pointer to the proper SPI Instance
<>	149:156823d33999	86	obj->spi.spi = (mxc_spi_regs_t*)spi;
<>	149:156823d33999	87
<>	149:156823d33999	88	// Set the SPI index and FIFOs
<>	149:156823d33999	89	obj->spi.index = MXC_SPI_GET_IDX(obj->spi.spi);
<>	149:156823d33999	90	obj->spi.fifo = MXC_SPI_GET_SPI_FIFO(obj->spi.index);
<>	149:156823d33999	91
<>	149:156823d33999	92	// Configure the pins
<>	149:156823d33999	93	pinmap_pinout(mosi, PinMap_SPI_MOSI);
<>	149:156823d33999	94	pinmap_pinout(miso, PinMap_SPI_MISO);
<>	149:156823d33999	95	pinmap_pinout(sclk, PinMap_SPI_SCLK);
<>	149:156823d33999	96	pinmap_pinout(ssel, PinMap_SPI_SSEL);
<>	149:156823d33999	97
<>	149:156823d33999	98	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	99	// Configure default page size; size is known to async interface
<>	149:156823d33999	100	obj->spi.spi->mstr_cfg = (obj->spi.spi->mstr_cfg & ~MXC_F_SPI_MSTR_CFG_PAGE_SIZE) \| MXC_S_SPI_MSTR_CFG_PAGE_32B;
<>	149:156823d33999	101	#endif
<>	149:156823d33999	102
<>	149:156823d33999	103	// Enable SPI and FIFOs
<>	149:156823d33999	104	obj->spi.spi->gen_ctrl = (MXC_F_SPI_GEN_CTRL_SPI_MSTR_EN \|
<>	149:156823d33999	105	MXC_F_SPI_GEN_CTRL_TX_FIFO_EN \|
<>	149:156823d33999	106	MXC_F_SPI_GEN_CTRL_RX_FIFO_EN );
<>	149:156823d33999	107
<>	149:156823d33999	108	obj->spi.sclk = sclk; // save the sclk PinName in the object as a key for Quad SPI pin mapping lookup
<>	149:156823d33999	109	spi_master_width(obj, 0); // default this for Single SPI communications
<>	149:156823d33999	110	}
<>	149:156823d33999	111
<>	149:156823d33999	112	//******************************************************************************
<>	149:156823d33999	113	void spi_format(spi_t *obj, int bits, int mode, int slave)
<>	149:156823d33999	114	{
<>	149:156823d33999	115	// Check the validity of the inputs
<>	149:156823d33999	116	MBED_ASSERT(((bits >= 1) && (bits <= 32)) && ((mode >= 0) && (mode <= 3)));
<>	149:156823d33999	117
<>	149:156823d33999	118	// Only supports master mode
<>	149:156823d33999	119	MBED_ASSERT(!slave);
<>	149:156823d33999	120
<>	149:156823d33999	121	// Save formatting data
<>	149:156823d33999	122	obj->spi.bits = bits;
<>	149:156823d33999	123
<>	149:156823d33999	124	// Set the mode
<>	149:156823d33999	125	MXC_SET_FIELD(&obj->spi.spi->mstr_cfg, MXC_F_SPI_MSTR_CFG_SPI_MODE, mode << MXC_F_SPI_MSTR_CFG_SPI_MODE_POS);
<>	149:156823d33999	126	}
<>	149:156823d33999	127
<>	149:156823d33999	128	//******************************************************************************
<>	149:156823d33999	129	void spi_frequency(spi_t *obj, int hz)
<>	149:156823d33999	130	{
<>	149:156823d33999	131	// Maximum frequency is half the system frequency
<>	149:156823d33999	132	MBED_ASSERT((unsigned int)hz <= (SystemCoreClock / 2));
<>	149:156823d33999	133	unsigned clocks = ((SystemCoreClock / 2) / hz);
<>	149:156823d33999	134
<>	149:156823d33999	135	// Figure out the divider ratio
<>	149:156823d33999	136	int clk_div = 1;
<>	149:156823d33999	137	while (clk_div < 10) {
<>	149:156823d33999	138	if (clocks < 0x10) {
<>	149:156823d33999	139	break;
<>	149:156823d33999	140	}
<>	149:156823d33999	141	clk_div++;
<>	149:156823d33999	142	clocks = clocks >> 1;
<>	149:156823d33999	143	}
<>	149:156823d33999	144
<>	149:156823d33999	145	// Turn on the SPI clock
<>	149:156823d33999	146	if (obj->spi.index == 0) {
<>	149:156823d33999	147	MXC_CLKMAN->sys_clk_ctrl_11_spi0 = clk_div;
<>	149:156823d33999	148	} else if (obj->spi.index == 1) {
<>	149:156823d33999	149	MXC_CLKMAN->sys_clk_ctrl_12_spi1 = clk_div;
<>	149:156823d33999	150	} else if (obj->spi.index == 2) {
<>	149:156823d33999	151	MXC_CLKMAN->sys_clk_ctrl_13_spi2 = clk_div;
<>	149:156823d33999	152	} else {
<>	149:156823d33999	153	MBED_ASSERT(0);
<>	149:156823d33999	154	}
<>	149:156823d33999	155
<>	149:156823d33999	156	// Set the number of clocks to hold sclk high and low
<>	149:156823d33999	157	MXC_SET_FIELD(&obj->spi.spi->mstr_cfg, (MXC_F_SPI_MSTR_CFG_SCK_HI_CLK \| MXC_F_SPI_MSTR_CFG_SCK_LO_CLK),
<>	149:156823d33999	158	((clocks << MXC_F_SPI_MSTR_CFG_SCK_HI_CLK_POS) \| (clocks << MXC_F_SPI_MSTR_CFG_SCK_LO_CLK_POS)));
<>	149:156823d33999	159	}
<>	149:156823d33999	160
<>	149:156823d33999	161	//******************************************************************************
<>	149:156823d33999	162	void spi_master_width(spi_t *obj, SpiWidth width)
<>	149:156823d33999	163	{
<>	149:156823d33999	164	// Save the width to be used in the SPI header
<>	149:156823d33999	165	switch (width) {
<>	149:156823d33999	166	case WidthSingle:
<>	149:156823d33999	167	obj->spi.width = MXC_S_SPI_FIFO_WIDTH_SINGLE;
<>	149:156823d33999	168	break;
<>	149:156823d33999	169	case WidthDual:
<>	149:156823d33999	170	obj->spi.width = MXC_S_SPI_FIFO_WIDTH_DUAL;
<>	149:156823d33999	171	break;
<>	149:156823d33999	172	case WidthQuad:
<>	149:156823d33999	173	obj->spi.width = MXC_S_SPI_FIFO_WIDTH_QUAD;
<>	149:156823d33999	174	// do pin mapping for SDIO[2] and SDIO[3] if Quad SPI is selected
<>	149:156823d33999	175	pinmap_pinout(obj->spi.sclk, PinMap_SPI_QUAD);
<>	149:156823d33999	176	break;
<>	149:156823d33999	177	default:
<>	149:156823d33999	178	MBED_ASSERT(0);
<>	149:156823d33999	179	}
<>	149:156823d33999	180	}
<>	149:156823d33999	181
<>	149:156823d33999	182	//******************************************************************************
<>	149:156823d33999	183	/** Performs a master write or read transaction
<>	149:156823d33999	184	*
<>	149:156823d33999	185	* @param[in] obj The SPI peripheral to use for sending
<>	149:156823d33999	186	* @param[in] value The value to send
<>	149:156823d33999	187	* @param[in] direction Direction of the transaction, TX, RX or both
<>	149:156823d33999	188	* @return Returns the value received during send
<>	149:156823d33999	189	*/
<>	149:156823d33999	190	static int spi_master_transaction(spi_t *obj, int value, uint32_t direction)
<>	149:156823d33999	191	{
<>	149:156823d33999	192	int bits;
<>	149:156823d33999	193
<>	149:156823d33999	194	// Create the header
<>	149:156823d33999	195	uint16_t header = (direction \| // direction based on SPI object
<>	149:156823d33999	196	MXC_S_SPI_FIFO_UNIT_BITS \| // unit size
<>	149:156823d33999	197	((obj->spi.bits == 32) ? 0 : obj->spi.bits << MXC_F_SPI_FIFO_SIZE_POS) \| // Number of units
<>	149:156823d33999	198	obj->spi.width \| // I/O width
<>	149:156823d33999	199	((obj->spi.ssel == -1) ? 0 : 1 << MXC_F_SPI_FIFO_DASS_POS));
<>	149:156823d33999	200
<>	149:156823d33999	201	// Send the message header
<>	149:156823d33999	202	*obj->spi.fifo->trans_16 = header;
<>	149:156823d33999	203
<>	149:156823d33999	204	// Send the data
<>	149:156823d33999	205	if (obj->spi.bits < 17) {
<>	149:156823d33999	206	*obj->spi.fifo->trans_16 = (uint16_t)value;
<>	149:156823d33999	207	} else {
<>	149:156823d33999	208	*obj->spi.fifo->trans_32 = (uint32_t)value;
<>	149:156823d33999	209	}
<>	149:156823d33999	210
<>	149:156823d33999	211	// Get the data
<>	149:156823d33999	212	bits = obj->spi.bits;
<>	149:156823d33999	213	int result = 0;
<>	149:156823d33999	214	int i = 0;
<>	149:156823d33999	215	while (bits > 0) {
<>	149:156823d33999	216	// Wait for data
<>	149:156823d33999	217	while (((obj->spi.spi->fifo_ctrl & MXC_F_SPI_FIFO_CTRL_RX_FIFO_USED)
<>	149:156823d33999	218	>> MXC_F_SPI_FIFO_CTRL_RX_FIFO_USED_POS) < 1);
<>	149:156823d33999	219
<>	149:156823d33999	220	result \|= (obj->spi.fifo->rslts_8 << (i++8));
<>	149:156823d33999	221	bits-=8;
<>	149:156823d33999	222	}
<>	149:156823d33999	223
<>	149:156823d33999	224	return result;
<>	149:156823d33999	225	}
<>	149:156823d33999	226
<>	149:156823d33999	227	//******************************************************************************
<>	149:156823d33999	228	int spi_master_write(spi_t *obj, int value)
<>	149:156823d33999	229	{
<>	149:156823d33999	230	// set the fifo direction for full duplex, TX and RX simultaneously
<>	149:156823d33999	231	return spi_master_transaction(obj, value, MXC_S_SPI_FIFO_DIR_BOTH);
<>	149:156823d33999	232	}
<>	149:156823d33999	233
<>	149:156823d33999	234	//******************************************************************************
<>	149:156823d33999	235	int spi_master_read(spi_t *obj)
<>	149:156823d33999	236	{
<>	149:156823d33999	237	return spi_master_transaction(obj, 0xFF, MXC_S_SPI_FIFO_DIR_RX);
<>	149:156823d33999	238	}
<>	149:156823d33999	239
<>	149:156823d33999	240	//******************************************************************************
<>	149:156823d33999	241	// spi_busy() is part of the synchronous API, it is not used by the asynchronous API.
<>	149:156823d33999	242	int spi_busy(spi_t *obj)
<>	149:156823d33999	243	{
<>	149:156823d33999	244	return !(obj->spi.spi->intfl & MXC_F_SPI_INTFL_TX_READY);
<>	149:156823d33999	245	}
<>	149:156823d33999	246
<>	149:156823d33999	247	#if DEVICE_SPI_ASYNCH
<>	149:156823d33999	248	//******************************************************************************
<>	149:156823d33999	249	static uint32_t spi_master_read_rxfifo(mxc_spi_regs_t spim, mxc_spi_fifo_regs_t fifo, uint8_t *data, uint32_t len)
<>	149:156823d33999	250	{
<>	149:156823d33999	251	uint32_t num = 0;
<>	149:156823d33999	252	uint32_t avail = ((spim->fifo_ctrl & MXC_F_SPI_FIFO_CTRL_RX_FIFO_USED) >> MXC_F_SPI_FIFO_CTRL_RX_FIFO_USED_POS);
<>	149:156823d33999	253
<>	149:156823d33999	254	// Get data from the RXFIFO
<>	149:156823d33999	255	while (avail && (len - num)) {
<>	149:156823d33999	256	// Save data from the RXFIFO
<>	149:156823d33999	257	if ((avail >= 4) && ((len - num) >= 4)) {
<>	149:156823d33999	258	uint32_t temp = *fifo->rslts_32;
<>	149:156823d33999	259	data[num++] = temp;
<>	149:156823d33999	260	data[num++] = temp >> 8;
<>	149:156823d33999	261	data[num++] = temp >> 16;
<>	149:156823d33999	262	data[num++] = temp >> 24;
<>	149:156823d33999	263	avail -= 4;
<>	149:156823d33999	264	} else if ((avail >= 2) && ((len - num) >= 2)) {
<>	149:156823d33999	265	uint16_t temp = *fifo->rslts_16;
<>	149:156823d33999	266	data[num++] = temp;
<>	149:156823d33999	267	data[num++] = temp >> 8;
<>	149:156823d33999	268	avail -= 2;
<>	149:156823d33999	269	} else {
<>	149:156823d33999	270	data[num++] = *fifo->rslts_8;
<>	149:156823d33999	271	avail--;
<>	149:156823d33999	272	}
<>	149:156823d33999	273
<>	149:156823d33999	274	// Check to see if there is more data in the FIFO
<>	149:156823d33999	275	if (avail == 0) {
<>	149:156823d33999	276	avail = ((spim->fifo_ctrl & MXC_F_SPI_FIFO_CTRL_RX_FIFO_USED) >> MXC_F_SPI_FIFO_CTRL_RX_FIFO_USED_POS);
<>	149:156823d33999	277	}
<>	149:156823d33999	278	}
<>	149:156823d33999	279
<>	149:156823d33999	280	return num;
<>	149:156823d33999	281	}
<>	149:156823d33999	282
<>	149:156823d33999	283	//******************************************************************************
<>	149:156823d33999	284	static uint32_t spi_master_transfer_handler(spi_t *obj)
<>	149:156823d33999	285	{
<>	149:156823d33999	286	uint8_t read;
<>	149:156823d33999	287	uint8_t write;
<>	149:156823d33999	288	uint16_t header;
<>	149:156823d33999	289	uint32_t pages;
<>	149:156823d33999	290	uint32_t bytes;
<>	149:156823d33999	291	uint32_t inten;
<>	149:156823d33999	292	unsigned remain;
<>	149:156823d33999	293	unsigned bytes_read;
<>	149:156823d33999	294	unsigned head_rem_temp;
<>	149:156823d33999	295	unsigned avail;
<>	149:156823d33999	296	struct spi_s *req = &obj->spi;
<>	149:156823d33999	297	mxc_spi_regs_t *spim = obj->spi.spi;
<>	149:156823d33999	298	mxc_spi_fifo_regs_t *fifo = obj->spi.fifo;
<>	149:156823d33999	299
<>	149:156823d33999	300	inten = 0;
<>	149:156823d33999	301
<>	149:156823d33999	302	// Figure out if we're reading
<>	149:156823d33999	303	read = (req->rx_data != NULL) ? 1 : 0;
<>	149:156823d33999	304
<>	149:156823d33999	305	// Figure out if we're writing
<>	149:156823d33999	306	write = (req->tx_data != NULL) ? 1 : 0;
<>	149:156823d33999	307
<>	149:156823d33999	308	// Read byte from the FIFO if we are reading
<>	149:156823d33999	309	if (read) {
<>	149:156823d33999	310
<>	149:156823d33999	311	// Read all of the data in the RXFIFO, or until we don't need anymore
<>	149:156823d33999	312	bytes_read = spi_master_read_rxfifo(spim, fifo, &req->rx_data[req->read_num], (req->len - req->read_num));
<>	149:156823d33999	313
<>	149:156823d33999	314	req->read_num += bytes_read;
<>	149:156823d33999	315
<>	149:156823d33999	316	// Adjust head_rem if we are only reading
<>	149:156823d33999	317	if (!write && (req->head_rem > 0)) {
<>	149:156823d33999	318	req->head_rem -= bytes_read;
<>	149:156823d33999	319	}
<>	149:156823d33999	320
<>	149:156823d33999	321	// Figure out how many bytes we have left to read
<>	149:156823d33999	322	if (req->head_rem > 0) {
<>	149:156823d33999	323	remain = req->head_rem;
<>	149:156823d33999	324	} else {
<>	149:156823d33999	325	remain = req->len - req->read_num;
<>	149:156823d33999	326	}
<>	149:156823d33999	327
<>	149:156823d33999	328	if (remain) {
<>	149:156823d33999	329
<>	149:156823d33999	330	// Set the RX interrupts
<>	149:156823d33999	331	if (remain > MXC_CFG_SPI_FIFO_DEPTH) {
<>	149:156823d33999	332	spim->fifo_ctrl = ((spim->fifo_ctrl & ~MXC_F_SPI_FIFO_CTRL_RX_FIFO_AF_LVL) \|
<>	149:156823d33999	333	((MXC_CFG_SPI_FIFO_DEPTH - 2) << MXC_F_SPI_FIFO_CTRL_RX_FIFO_AF_LVL_POS));
<>	149:156823d33999	334	} else {
<>	149:156823d33999	335	spim->fifo_ctrl = ((spim->fifo_ctrl & ~MXC_F_SPI_FIFO_CTRL_RX_FIFO_AF_LVL) \|
<>	149:156823d33999	336	((remain - 1) << MXC_F_SPI_FIFO_CTRL_RX_FIFO_AF_LVL_POS));
<>	149:156823d33999	337	}
<>	149:156823d33999	338
<>	149:156823d33999	339	inten \|= MXC_F_SPI_INTEN_RX_FIFO_AF;
<>	149:156823d33999	340	}
<>	149:156823d33999	341	}
<>	149:156823d33999	342
<>	149:156823d33999	343	// Figure out how many bytes we have left to send headers for
<>	149:156823d33999	344	if (write) {
<>	149:156823d33999	345	remain = req->len - req->write_num;
<>	149:156823d33999	346	} else {
<>	149:156823d33999	347	remain = req->len - req->read_num;
<>	149:156823d33999	348	}
<>	149:156823d33999	349
<>	149:156823d33999	350	// See if we need to send a new header
<>	149:156823d33999	351	if ((req->head_rem <= 0) && remain) {
<>	149:156823d33999	352
<>	149:156823d33999	353	// Set the transaction configuration in the header
<>	149:156823d33999	354	header = ((write \| (read << 1)) << MXC_F_SPI_FIFO_DIR_POS) \| (req->width << MXC_F_SPI_FIFO_WIDTH_POS);
<>	149:156823d33999	355
<>	149:156823d33999	356	if (remain >= SPI_MAX_BYTE_LEN) {
<>	149:156823d33999	357
<>	149:156823d33999	358	// Send a 32 byte header
<>	149:156823d33999	359	if (remain == SPI_MAX_BYTE_LEN) {
<>	149:156823d33999	360
<>	149:156823d33999	361	header \|= (MXC_S_SPI_FIFO_UNIT_BYTES \| MXC_F_SPI_FIFO_DASS);
<>	149:156823d33999	362
<>	149:156823d33999	363	// Save the number of bytes we need to write to the FIFO
<>	149:156823d33999	364	bytes = SPI_MAX_BYTE_LEN;
<>	149:156823d33999	365
<>	149:156823d33999	366	} else {
<>	149:156823d33999	367	// Send in increments of 32 byte pages
<>	149:156823d33999	368	header \|= MXC_S_SPI_FIFO_UNIT_PAGES;
<>	149:156823d33999	369	pages = remain / SPI_MAX_PAGE_LEN;
<>	149:156823d33999	370
<>	149:156823d33999	371	if (pages >= 32) {
<>	149:156823d33999	372	// 0 maps to 32 in the header
<>	149:156823d33999	373	bytes = 32 * SPI_MAX_PAGE_LEN;
<>	149:156823d33999	374	} else {
<>	149:156823d33999	375	header \|= (pages << MXC_F_SPI_FIFO_SIZE_POS);
<>	149:156823d33999	376	bytes = pages * SPI_MAX_PAGE_LEN;
<>	149:156823d33999	377	}
<>	149:156823d33999	378
<>	149:156823d33999	379	// Check if this is the last header we will send
<>	149:156823d33999	380	if ((remain - bytes) == 0) {
<>	149:156823d33999	381	header \|= MXC_F_SPI_FIFO_DASS;
<>	149:156823d33999	382	}
<>	149:156823d33999	383	}
<>	149:156823d33999	384
<>	149:156823d33999	385	fifo->trans_16[0] = header;
<>	149:156823d33999	386
<>	149:156823d33999	387	// Save the number of bytes we need to write to the FIFO
<>	149:156823d33999	388	req->head_rem = bytes;
<>	149:156823d33999	389
<>	149:156823d33999	390	} else {
<>	149:156823d33999	391	// Send final header with the number of bytes remaining and de-assert the SS at the end of the transaction
<>	149:156823d33999	392	header \|= (MXC_S_SPI_FIFO_UNIT_BYTES \| (remain << MXC_F_SPI_FIFO_SIZE_POS) \| MXC_F_SPI_FIFO_DASS);
<>	149:156823d33999	393	fifo->trans_16[0] = header;
<>	149:156823d33999	394	req->head_rem = remain;
<>	149:156823d33999	395	}
<>	149:156823d33999	396	}
<>	149:156823d33999	397
<>	149:156823d33999	398	// Put data into the FIFO if we are writing
<>	149:156823d33999	399	remain = req->len - req->write_num;
<>	149:156823d33999	400	head_rem_temp = req->head_rem;
<>	149:156823d33999	401	if (write && head_rem_temp) {
<>	149:156823d33999	402
<>	149:156823d33999	403	// Fill the FIFO
<>	149:156823d33999	404	avail = (MXC_CFG_SPI_FIFO_DEPTH - ((spim->fifo_ctrl & MXC_F_SPI_FIFO_CTRL_TX_FIFO_USED) >> MXC_F_SPI_FIFO_CTRL_TX_FIFO_USED_POS));
<>	149:156823d33999	405
<>	149:156823d33999	406	// Use memcpy for everything except the last byte in odd length transactions
<>	149:156823d33999	407	while ((avail >= 2) && (head_rem_temp >= 2)) {
<>	149:156823d33999	408
<>	149:156823d33999	409	unsigned length;
<>	149:156823d33999	410	if (head_rem_temp < avail) {
<>	149:156823d33999	411	length = head_rem_temp;
<>	149:156823d33999	412	} else {
<>	149:156823d33999	413	length = avail;
<>	149:156823d33999	414	}
<>	149:156823d33999	415
<>	149:156823d33999	416	// Only memcpy even numbers
<>	149:156823d33999	417	length = ((length / 2) * 2);
<>	149:156823d33999	418
<>	149:156823d33999	419	memcpy((void*)fifo->trans_32, &(req->tx_data[req->write_num]), length);
<>	149:156823d33999	420
<>	149:156823d33999	421	head_rem_temp -= length;
<>	149:156823d33999	422	req->write_num += length;
<>	149:156823d33999	423
<>	149:156823d33999	424	avail = (MXC_CFG_SPI_FIFO_DEPTH - ((spim->fifo_ctrl & MXC_F_SPI_FIFO_CTRL_TX_FIFO_USED) >> MXC_F_SPI_FIFO_CTRL_TX_FIFO_USED_POS));
<>	149:156823d33999	425	}
<>	149:156823d33999	426
<>	149:156823d33999	427	// Copy the last byte and pad with 0xF0 to not get confused as header
<>	149:156823d33999	428	if ((avail >= 1) && (head_rem_temp == 1)) {
<>	149:156823d33999	429
<>	149:156823d33999	430	// Write the last byte
<>	149:156823d33999	431	fifo->trans_16[0] = (0xF000 \| req->tx_data[req->write_num]);
<>	149:156823d33999	432
<>	149:156823d33999	433	avail -= 1;
<>	149:156823d33999	434	req->write_num += 1;
<>	149:156823d33999	435	head_rem_temp -= 1;
<>	149:156823d33999	436	}
<>	149:156823d33999	437
<>	149:156823d33999	438	req->head_rem = head_rem_temp;
<>	149:156823d33999	439	remain = req->len - req->write_num;
<>	149:156823d33999	440
<>	149:156823d33999	441	// Set the TX interrupts
<>	149:156823d33999	442	if (remain) {
<>	149:156823d33999	443
<>	149:156823d33999	444	// Set the TX FIFO almost empty interrupt if we have to refill
<>	149:156823d33999	445	spim->fifo_ctrl = ((spim->fifo_ctrl & ~MXC_F_SPI_FIFO_CTRL_TX_FIFO_AE_LVL) \|
<>	149:156823d33999	446	((MXC_CFG_SPI_FIFO_DEPTH - 2) << MXC_F_SPI_FIFO_CTRL_TX_FIFO_AE_LVL_POS));
<>	149:156823d33999	447
<>	149:156823d33999	448	inten \|= MXC_F_SPI_INTEN_TX_FIFO_AE;
<>	149:156823d33999	449	}
<>	149:156823d33999	450	}
<>	149:156823d33999	451
<>	149:156823d33999	452	// Check to see if we've finished reading and writing
<>	149:156823d33999	453	if (((read && (req->read_num == req->len)) \|\| !read) &&
<>	149:156823d33999	454	((req->write_num == req->len) \|\| !write)) {
<>	149:156823d33999	455
<>	149:156823d33999	456	// Disable interrupts
<>	149:156823d33999	457	spim->inten = 0;
<>	149:156823d33999	458	}
<>	149:156823d33999	459
<>	149:156823d33999	460	// Enable the SPIM interrupts
<>	149:156823d33999	461	return inten;
<>	149:156823d33999	462	}
<>	149:156823d33999	463
<>	149:156823d33999	464	//******************************************************************************
<>	149:156823d33999	465	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	466	{
<>	149:156823d33999	467	MBED_ASSERT(tx_length == rx_length);
<>	149:156823d33999	468	MBED_ASSERT(bit_width == obj->spi.bits);
<>	149:156823d33999	469
<>	149:156823d33999	470	// Save object reference for callback
<>	149:156823d33999	471	state[obj->spi.index] = &obj->spi;
<>	149:156823d33999	472
<>	149:156823d33999	473	// Initialize request info
<>	149:156823d33999	474	obj->spi.tx_data = tx;
<>	149:156823d33999	475	obj->spi.rx_data = rx;
<>	149:156823d33999	476	obj->spi.len = tx_length;
<>	149:156823d33999	477	obj->spi.callback = (void(*)())handler;
<>	149:156823d33999	478	obj->spi.event = event;
<>	149:156823d33999	479	// Clear transfer state
<>	149:156823d33999	480	obj->spi.read_num = 0;
<>	149:156823d33999	481	obj->spi.write_num = 0;
<>	149:156823d33999	482	obj->spi.head_rem = 0;
<>	149:156823d33999	483
<>	149:156823d33999	484	NVIC_EnableIRQ(MXC_SPI_GET_IRQ(obj->spi.index));
<>	149:156823d33999	485
<>	149:156823d33999	486	obj->spi.spi->inten = spi_master_transfer_handler(obj);
<>	149:156823d33999	487	}
<>	149:156823d33999	488
<>	149:156823d33999	489	//******************************************************************************
<>	149:156823d33999	490	uint32_t spi_irq_handler_asynch(spi_t *obj)
<>	149:156823d33999	491	{
<>	149:156823d33999	492	mxc_spi_regs_t *spim = obj->spi.spi;
<>	149:156823d33999	493	uint32_t flags;
<>	149:156823d33999	494
<>	149:156823d33999	495	// Clear the interrupt flags
<>	149:156823d33999	496	spim->inten = 0;
<>	149:156823d33999	497	flags = spim->intfl;
<>	149:156823d33999	498	spim->intfl = flags;
<>	149:156823d33999	499
<>	149:156823d33999	500	// Figure out if this SPIM has an active request
<>	149:156823d33999	501	if (flags) {
<>	149:156823d33999	502	if ((spim->inten = spi_master_transfer_handler(obj)) != 0) {
<>	149:156823d33999	503	return 0;
<>	149:156823d33999	504	}
<>	149:156823d33999	505	}
<>	149:156823d33999	506
<>	149:156823d33999	507	state[obj->spi.index] = NULL;
<>	149:156823d33999	508
<>	149:156823d33999	509	return SPI_EVENT_COMPLETE;
<>	149:156823d33999	510	}
<>	149:156823d33999	511
<>	149:156823d33999	512	//******************************************************************************
<>	149:156823d33999	513	uint8_t spi_active(spi_t *obj)
<>	149:156823d33999	514	{
<>	149:156823d33999	515	mxc_spi_regs_t *spim = obj->spi.spi;
<>	149:156823d33999	516
<>	149:156823d33999	517	// Check to see if there are any ongoing transactions
<>	149:156823d33999	518	if ((state[obj->spi.index] == NULL) &&
<>	149:156823d33999	519	!(spim->fifo_ctrl & MXC_F_SPI_FIFO_CTRL_TX_FIFO_USED)) {
<>	149:156823d33999	520	return 0;
<>	149:156823d33999	521	}
<>	149:156823d33999	522
<>	149:156823d33999	523	return 1;
<>	149:156823d33999	524	}
<>	149:156823d33999	525
<>	149:156823d33999	526	//******************************************************************************
<>	149:156823d33999	527	void spi_abort_asynch(spi_t *obj)
<>	149:156823d33999	528	{
<>	149:156823d33999	529	mxc_spi_regs_t *spim = obj->spi.spi;
<>	149:156823d33999	530
<>	149:156823d33999	531	// Disable interrupts, clear the flags
<>	149:156823d33999	532	spim->inten = 0;
<>	149:156823d33999	533	spim->intfl = spim->intfl;
<>	149:156823d33999	534
<>	149:156823d33999	535	// Reset the SPIM to cancel the on ongoing transaction
<>	149:156823d33999	536	spim->gen_ctrl &= ~(MXC_F_SPI_GEN_CTRL_SPI_MSTR_EN);
<>	149:156823d33999	537	spim->gen_ctrl \|= (MXC_F_SPI_GEN_CTRL_SPI_MSTR_EN);
<>	149:156823d33999	538
<>	149:156823d33999	539	state[obj->spi.index] = NULL;
<>	149:156823d33999	540	}
<>	149:156823d33999	541
<>	149:156823d33999	542	//******************************************************************************
<>	149:156823d33999	543	static void SPI_IRQHandler(int spim_num)
<>	149:156823d33999	544	{
<>	149:156823d33999	545	if (state[spim_num] != NULL) {
<>	149:156823d33999	546	if (state[spim_num]->callback != NULL) {
<>	149:156823d33999	547	state[spim_num]->callback();
<>	149:156823d33999	548	return;
<>	149:156823d33999	549	}
<>	149:156823d33999	550	}
<>	149:156823d33999	551	mxc_spi_regs_t *spim = MXC_SPI_GET_SPI(spim_num);
<>	149:156823d33999	552	spim->inten = 0;
<>	149:156823d33999	553	}
<>	149:156823d33999	554
<>	149:156823d33999	555	//******************************************************************************
<>	149:156823d33999	556	void SPI0_IRQHandler(void) { SPI_IRQHandler(0); }
<>	149:156823d33999	557	void SPI1_IRQHandler(void) { SPI_IRQHandler(1); }
<>	149:156823d33999	558	void SPI2_IRQHandler(void) { SPI_IRQHandler(2); }
<>	149:156823d33999	559
<>	149:156823d33999	560	#endif

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Type:	Library
Created:	09 Nov 2016
Imports:	0
Forks:	0
Commits:	152
Dependents:	0
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targets/TARGET_Maxim/TARGET_MAX32620/spi_api.c@149:156823d33999, 2016-10-28 (annotated)

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