linux_dsm_epyc7002/drivers/spi/spi-stm32.c
Linus Walleij 8a6553ecdf
spi: stm32: Switch to use GPIO descriptors for CS
This switches the STM32 SPI driver over to using GPIO
descriptors for chip select. Instead of the callbacks for
picking the GPIO lines using the legacy API we just let
the core handle it all using descriptors.

Cc: Fabien Dessenne <fabien.dessenne@st.com>
Cc: Amelie Delaunay <amelie.delaunay@st.com>
Cc: Cezary Gapinski <cezary.gapinski@gmail.com>
Signed-off-by: Linus Walleij <linus.walleij@linaro.org>
Link: https://lore.kernel.org/r/20191205083401.27077-1-linus.walleij@linaro.org
Signed-off-by: Mark Brown <broonie@kernel.org>
2019-12-09 18:46:13 +00:00

2024 lines
56 KiB
C

// SPDX-License-Identifier: GPL-2.0
//
// STMicroelectronics STM32 SPI Controller driver (master mode only)
//
// Copyright (C) 2017, STMicroelectronics - All Rights Reserved
// Author(s): Amelie Delaunay <amelie.delaunay@st.com> for STMicroelectronics.
#include <linux/debugfs.h>
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/dmaengine.h>
#include <linux/interrupt.h>
#include <linux/iopoll.h>
#include <linux/module.h>
#include <linux/of_platform.h>
#include <linux/pm_runtime.h>
#include <linux/reset.h>
#include <linux/spi/spi.h>
#define DRIVER_NAME "spi_stm32"
/* STM32F4 SPI registers */
#define STM32F4_SPI_CR1 0x00
#define STM32F4_SPI_CR2 0x04
#define STM32F4_SPI_SR 0x08
#define STM32F4_SPI_DR 0x0C
#define STM32F4_SPI_I2SCFGR 0x1C
/* STM32F4_SPI_CR1 bit fields */
#define STM32F4_SPI_CR1_CPHA BIT(0)
#define STM32F4_SPI_CR1_CPOL BIT(1)
#define STM32F4_SPI_CR1_MSTR BIT(2)
#define STM32F4_SPI_CR1_BR_SHIFT 3
#define STM32F4_SPI_CR1_BR GENMASK(5, 3)
#define STM32F4_SPI_CR1_SPE BIT(6)
#define STM32F4_SPI_CR1_LSBFRST BIT(7)
#define STM32F4_SPI_CR1_SSI BIT(8)
#define STM32F4_SPI_CR1_SSM BIT(9)
#define STM32F4_SPI_CR1_RXONLY BIT(10)
#define STM32F4_SPI_CR1_DFF BIT(11)
#define STM32F4_SPI_CR1_CRCNEXT BIT(12)
#define STM32F4_SPI_CR1_CRCEN BIT(13)
#define STM32F4_SPI_CR1_BIDIOE BIT(14)
#define STM32F4_SPI_CR1_BIDIMODE BIT(15)
#define STM32F4_SPI_CR1_BR_MIN 0
#define STM32F4_SPI_CR1_BR_MAX (GENMASK(5, 3) >> 3)
/* STM32F4_SPI_CR2 bit fields */
#define STM32F4_SPI_CR2_RXDMAEN BIT(0)
#define STM32F4_SPI_CR2_TXDMAEN BIT(1)
#define STM32F4_SPI_CR2_SSOE BIT(2)
#define STM32F4_SPI_CR2_FRF BIT(4)
#define STM32F4_SPI_CR2_ERRIE BIT(5)
#define STM32F4_SPI_CR2_RXNEIE BIT(6)
#define STM32F4_SPI_CR2_TXEIE BIT(7)
/* STM32F4_SPI_SR bit fields */
#define STM32F4_SPI_SR_RXNE BIT(0)
#define STM32F4_SPI_SR_TXE BIT(1)
#define STM32F4_SPI_SR_CHSIDE BIT(2)
#define STM32F4_SPI_SR_UDR BIT(3)
#define STM32F4_SPI_SR_CRCERR BIT(4)
#define STM32F4_SPI_SR_MODF BIT(5)
#define STM32F4_SPI_SR_OVR BIT(6)
#define STM32F4_SPI_SR_BSY BIT(7)
#define STM32F4_SPI_SR_FRE BIT(8)
/* STM32F4_SPI_I2SCFGR bit fields */
#define STM32F4_SPI_I2SCFGR_I2SMOD BIT(11)
/* STM32F4 SPI Baud Rate min/max divisor */
#define STM32F4_SPI_BR_DIV_MIN (2 << STM32F4_SPI_CR1_BR_MIN)
#define STM32F4_SPI_BR_DIV_MAX (2 << STM32F4_SPI_CR1_BR_MAX)
/* STM32H7 SPI registers */
#define STM32H7_SPI_CR1 0x00
#define STM32H7_SPI_CR2 0x04
#define STM32H7_SPI_CFG1 0x08
#define STM32H7_SPI_CFG2 0x0C
#define STM32H7_SPI_IER 0x10
#define STM32H7_SPI_SR 0x14
#define STM32H7_SPI_IFCR 0x18
#define STM32H7_SPI_TXDR 0x20
#define STM32H7_SPI_RXDR 0x30
#define STM32H7_SPI_I2SCFGR 0x50
/* STM32H7_SPI_CR1 bit fields */
#define STM32H7_SPI_CR1_SPE BIT(0)
#define STM32H7_SPI_CR1_MASRX BIT(8)
#define STM32H7_SPI_CR1_CSTART BIT(9)
#define STM32H7_SPI_CR1_CSUSP BIT(10)
#define STM32H7_SPI_CR1_HDDIR BIT(11)
#define STM32H7_SPI_CR1_SSI BIT(12)
/* STM32H7_SPI_CR2 bit fields */
#define STM32H7_SPI_CR2_TSIZE_SHIFT 0
#define STM32H7_SPI_CR2_TSIZE GENMASK(15, 0)
/* STM32H7_SPI_CFG1 bit fields */
#define STM32H7_SPI_CFG1_DSIZE_SHIFT 0
#define STM32H7_SPI_CFG1_DSIZE GENMASK(4, 0)
#define STM32H7_SPI_CFG1_FTHLV_SHIFT 5
#define STM32H7_SPI_CFG1_FTHLV GENMASK(8, 5)
#define STM32H7_SPI_CFG1_RXDMAEN BIT(14)
#define STM32H7_SPI_CFG1_TXDMAEN BIT(15)
#define STM32H7_SPI_CFG1_MBR_SHIFT 28
#define STM32H7_SPI_CFG1_MBR GENMASK(30, 28)
#define STM32H7_SPI_CFG1_MBR_MIN 0
#define STM32H7_SPI_CFG1_MBR_MAX (GENMASK(30, 28) >> 28)
/* STM32H7_SPI_CFG2 bit fields */
#define STM32H7_SPI_CFG2_MIDI_SHIFT 4
#define STM32H7_SPI_CFG2_MIDI GENMASK(7, 4)
#define STM32H7_SPI_CFG2_COMM_SHIFT 17
#define STM32H7_SPI_CFG2_COMM GENMASK(18, 17)
#define STM32H7_SPI_CFG2_SP_SHIFT 19
#define STM32H7_SPI_CFG2_SP GENMASK(21, 19)
#define STM32H7_SPI_CFG2_MASTER BIT(22)
#define STM32H7_SPI_CFG2_LSBFRST BIT(23)
#define STM32H7_SPI_CFG2_CPHA BIT(24)
#define STM32H7_SPI_CFG2_CPOL BIT(25)
#define STM32H7_SPI_CFG2_SSM BIT(26)
#define STM32H7_SPI_CFG2_AFCNTR BIT(31)
/* STM32H7_SPI_IER bit fields */
#define STM32H7_SPI_IER_RXPIE BIT(0)
#define STM32H7_SPI_IER_TXPIE BIT(1)
#define STM32H7_SPI_IER_DXPIE BIT(2)
#define STM32H7_SPI_IER_EOTIE BIT(3)
#define STM32H7_SPI_IER_TXTFIE BIT(4)
#define STM32H7_SPI_IER_OVRIE BIT(6)
#define STM32H7_SPI_IER_MODFIE BIT(9)
#define STM32H7_SPI_IER_ALL GENMASK(10, 0)
/* STM32H7_SPI_SR bit fields */
#define STM32H7_SPI_SR_RXP BIT(0)
#define STM32H7_SPI_SR_TXP BIT(1)
#define STM32H7_SPI_SR_EOT BIT(3)
#define STM32H7_SPI_SR_OVR BIT(6)
#define STM32H7_SPI_SR_MODF BIT(9)
#define STM32H7_SPI_SR_SUSP BIT(11)
#define STM32H7_SPI_SR_RXPLVL_SHIFT 13
#define STM32H7_SPI_SR_RXPLVL GENMASK(14, 13)
#define STM32H7_SPI_SR_RXWNE BIT(15)
/* STM32H7_SPI_IFCR bit fields */
#define STM32H7_SPI_IFCR_ALL GENMASK(11, 3)
/* STM32H7_SPI_I2SCFGR bit fields */
#define STM32H7_SPI_I2SCFGR_I2SMOD BIT(0)
/* STM32H7 SPI Master Baud Rate min/max divisor */
#define STM32H7_SPI_MBR_DIV_MIN (2 << STM32H7_SPI_CFG1_MBR_MIN)
#define STM32H7_SPI_MBR_DIV_MAX (2 << STM32H7_SPI_CFG1_MBR_MAX)
/* STM32H7 SPI Communication mode */
#define STM32H7_SPI_FULL_DUPLEX 0
#define STM32H7_SPI_SIMPLEX_TX 1
#define STM32H7_SPI_SIMPLEX_RX 2
#define STM32H7_SPI_HALF_DUPLEX 3
/* SPI Communication type */
#define SPI_FULL_DUPLEX 0
#define SPI_SIMPLEX_TX 1
#define SPI_SIMPLEX_RX 2
#define SPI_3WIRE_TX 3
#define SPI_3WIRE_RX 4
#define SPI_1HZ_NS 1000000000
/*
* use PIO for small transfers, avoiding DMA setup/teardown overhead for drivers
* without fifo buffers.
*/
#define SPI_DMA_MIN_BYTES 16
/**
* stm32_spi_reg - stm32 SPI register & bitfield desc
* @reg: register offset
* @mask: bitfield mask
* @shift: left shift
*/
struct stm32_spi_reg {
int reg;
int mask;
int shift;
};
/**
* stm32_spi_regspec - stm32 registers definition, compatible dependent data
* en: enable register and SPI enable bit
* dma_rx_en: SPI DMA RX enable register end SPI DMA RX enable bit
* dma_tx_en: SPI DMA TX enable register end SPI DMA TX enable bit
* cpol: clock polarity register and polarity bit
* cpha: clock phase register and phase bit
* lsb_first: LSB transmitted first register and bit
* br: baud rate register and bitfields
* rx: SPI RX data register
* tx: SPI TX data register
*/
struct stm32_spi_regspec {
const struct stm32_spi_reg en;
const struct stm32_spi_reg dma_rx_en;
const struct stm32_spi_reg dma_tx_en;
const struct stm32_spi_reg cpol;
const struct stm32_spi_reg cpha;
const struct stm32_spi_reg lsb_first;
const struct stm32_spi_reg br;
const struct stm32_spi_reg rx;
const struct stm32_spi_reg tx;
};
struct stm32_spi;
/**
* stm32_spi_cfg - stm32 compatible configuration data
* @regs: registers descriptions
* @get_fifo_size: routine to get fifo size
* @get_bpw_mask: routine to get bits per word mask
* @disable: routine to disable controller
* @config: routine to configure controller as SPI Master
* @set_bpw: routine to configure registers to for bits per word
* @set_mode: routine to configure registers to desired mode
* @set_data_idleness: optional routine to configure registers to desired idle
* time between frames (if driver has this functionality)
* set_number_of_data: optional routine to configure registers to desired
* number of data (if driver has this functionality)
* @can_dma: routine to determine if the transfer is eligible for DMA use
* @transfer_one_dma_start: routine to start transfer a single spi_transfer
* using DMA
* @dma_rx cb: routine to call after DMA RX channel operation is complete
* @dma_tx cb: routine to call after DMA TX channel operation is complete
* @transfer_one_irq: routine to configure interrupts for driver
* @irq_handler_event: Interrupt handler for SPI controller events
* @irq_handler_thread: thread of interrupt handler for SPI controller
* @baud_rate_div_min: minimum baud rate divisor
* @baud_rate_div_max: maximum baud rate divisor
* @has_fifo: boolean to know if fifo is used for driver
* @has_startbit: boolean to know if start bit is used to start transfer
*/
struct stm32_spi_cfg {
const struct stm32_spi_regspec *regs;
int (*get_fifo_size)(struct stm32_spi *spi);
int (*get_bpw_mask)(struct stm32_spi *spi);
void (*disable)(struct stm32_spi *spi);
int (*config)(struct stm32_spi *spi);
void (*set_bpw)(struct stm32_spi *spi);
int (*set_mode)(struct stm32_spi *spi, unsigned int comm_type);
void (*set_data_idleness)(struct stm32_spi *spi, u32 length);
int (*set_number_of_data)(struct stm32_spi *spi, u32 length);
void (*transfer_one_dma_start)(struct stm32_spi *spi);
void (*dma_rx_cb)(void *data);
void (*dma_tx_cb)(void *data);
int (*transfer_one_irq)(struct stm32_spi *spi);
irqreturn_t (*irq_handler_event)(int irq, void *dev_id);
irqreturn_t (*irq_handler_thread)(int irq, void *dev_id);
unsigned int baud_rate_div_min;
unsigned int baud_rate_div_max;
bool has_fifo;
};
/**
* struct stm32_spi - private data of the SPI controller
* @dev: driver model representation of the controller
* @master: controller master interface
* @cfg: compatible configuration data
* @base: virtual memory area
* @clk: hw kernel clock feeding the SPI clock generator
* @clk_rate: rate of the hw kernel clock feeding the SPI clock generator
* @rst: SPI controller reset line
* @lock: prevent I/O concurrent access
* @irq: SPI controller interrupt line
* @fifo_size: size of the embedded fifo in bytes
* @cur_midi: master inter-data idleness in ns
* @cur_speed: speed configured in Hz
* @cur_bpw: number of bits in a single SPI data frame
* @cur_fthlv: fifo threshold level (data frames in a single data packet)
* @cur_comm: SPI communication mode
* @cur_xferlen: current transfer length in bytes
* @cur_usedma: boolean to know if dma is used in current transfer
* @tx_buf: data to be written, or NULL
* @rx_buf: data to be read, or NULL
* @tx_len: number of data to be written in bytes
* @rx_len: number of data to be read in bytes
* @dma_tx: dma channel for TX transfer
* @dma_rx: dma channel for RX transfer
* @phys_addr: SPI registers physical base address
*/
struct stm32_spi {
struct device *dev;
struct spi_master *master;
const struct stm32_spi_cfg *cfg;
void __iomem *base;
struct clk *clk;
u32 clk_rate;
struct reset_control *rst;
spinlock_t lock; /* prevent I/O concurrent access */
int irq;
unsigned int fifo_size;
unsigned int cur_midi;
unsigned int cur_speed;
unsigned int cur_bpw;
unsigned int cur_fthlv;
unsigned int cur_comm;
unsigned int cur_xferlen;
bool cur_usedma;
const void *tx_buf;
void *rx_buf;
int tx_len;
int rx_len;
struct dma_chan *dma_tx;
struct dma_chan *dma_rx;
dma_addr_t phys_addr;
};
static const struct stm32_spi_regspec stm32f4_spi_regspec = {
.en = { STM32F4_SPI_CR1, STM32F4_SPI_CR1_SPE },
.dma_rx_en = { STM32F4_SPI_CR2, STM32F4_SPI_CR2_RXDMAEN },
.dma_tx_en = { STM32F4_SPI_CR2, STM32F4_SPI_CR2_TXDMAEN },
.cpol = { STM32F4_SPI_CR1, STM32F4_SPI_CR1_CPOL },
.cpha = { STM32F4_SPI_CR1, STM32F4_SPI_CR1_CPHA },
.lsb_first = { STM32F4_SPI_CR1, STM32F4_SPI_CR1_LSBFRST },
.br = { STM32F4_SPI_CR1, STM32F4_SPI_CR1_BR, STM32F4_SPI_CR1_BR_SHIFT },
.rx = { STM32F4_SPI_DR },
.tx = { STM32F4_SPI_DR },
};
static const struct stm32_spi_regspec stm32h7_spi_regspec = {
/* SPI data transfer is enabled but spi_ker_ck is idle.
* CFG1 and CFG2 registers are write protected when SPE is enabled.
*/
.en = { STM32H7_SPI_CR1, STM32H7_SPI_CR1_SPE },
.dma_rx_en = { STM32H7_SPI_CFG1, STM32H7_SPI_CFG1_RXDMAEN },
.dma_tx_en = { STM32H7_SPI_CFG1, STM32H7_SPI_CFG1_TXDMAEN },
.cpol = { STM32H7_SPI_CFG2, STM32H7_SPI_CFG2_CPOL },
.cpha = { STM32H7_SPI_CFG2, STM32H7_SPI_CFG2_CPHA },
.lsb_first = { STM32H7_SPI_CFG2, STM32H7_SPI_CFG2_LSBFRST },
.br = { STM32H7_SPI_CFG1, STM32H7_SPI_CFG1_MBR,
STM32H7_SPI_CFG1_MBR_SHIFT },
.rx = { STM32H7_SPI_RXDR },
.tx = { STM32H7_SPI_TXDR },
};
static inline void stm32_spi_set_bits(struct stm32_spi *spi,
u32 offset, u32 bits)
{
writel_relaxed(readl_relaxed(spi->base + offset) | bits,
spi->base + offset);
}
static inline void stm32_spi_clr_bits(struct stm32_spi *spi,
u32 offset, u32 bits)
{
writel_relaxed(readl_relaxed(spi->base + offset) & ~bits,
spi->base + offset);
}
/**
* stm32h7_spi_get_fifo_size - Return fifo size
* @spi: pointer to the spi controller data structure
*/
static int stm32h7_spi_get_fifo_size(struct stm32_spi *spi)
{
unsigned long flags;
u32 count = 0;
spin_lock_irqsave(&spi->lock, flags);
stm32_spi_set_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_SPE);
while (readl_relaxed(spi->base + STM32H7_SPI_SR) & STM32H7_SPI_SR_TXP)
writeb_relaxed(++count, spi->base + STM32H7_SPI_TXDR);
stm32_spi_clr_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_SPE);
spin_unlock_irqrestore(&spi->lock, flags);
dev_dbg(spi->dev, "%d x 8-bit fifo size\n", count);
return count;
}
/**
* stm32f4_spi_get_bpw_mask - Return bits per word mask
* @spi: pointer to the spi controller data structure
*/
static int stm32f4_spi_get_bpw_mask(struct stm32_spi *spi)
{
dev_dbg(spi->dev, "8-bit or 16-bit data frame supported\n");
return SPI_BPW_MASK(8) | SPI_BPW_MASK(16);
}
/**
* stm32h7_spi_get_bpw_mask - Return bits per word mask
* @spi: pointer to the spi controller data structure
*/
static int stm32h7_spi_get_bpw_mask(struct stm32_spi *spi)
{
unsigned long flags;
u32 cfg1, max_bpw;
spin_lock_irqsave(&spi->lock, flags);
/*
* The most significant bit at DSIZE bit field is reserved when the
* maximum data size of periperal instances is limited to 16-bit
*/
stm32_spi_set_bits(spi, STM32H7_SPI_CFG1, STM32H7_SPI_CFG1_DSIZE);
cfg1 = readl_relaxed(spi->base + STM32H7_SPI_CFG1);
max_bpw = (cfg1 & STM32H7_SPI_CFG1_DSIZE) >>
STM32H7_SPI_CFG1_DSIZE_SHIFT;
max_bpw += 1;
spin_unlock_irqrestore(&spi->lock, flags);
dev_dbg(spi->dev, "%d-bit maximum data frame\n", max_bpw);
return SPI_BPW_RANGE_MASK(4, max_bpw);
}
/**
* stm32_spi_prepare_mbr - Determine baud rate divisor value
* @spi: pointer to the spi controller data structure
* @speed_hz: requested speed
* @min_div: minimum baud rate divisor
* @max_div: maximum baud rate divisor
*
* Return baud rate divisor value in case of success or -EINVAL
*/
static int stm32_spi_prepare_mbr(struct stm32_spi *spi, u32 speed_hz,
u32 min_div, u32 max_div)
{
u32 div, mbrdiv;
div = DIV_ROUND_UP(spi->clk_rate, speed_hz);
/*
* SPI framework set xfer->speed_hz to master->max_speed_hz if
* xfer->speed_hz is greater than master->max_speed_hz, and it returns
* an error when xfer->speed_hz is lower than master->min_speed_hz, so
* no need to check it there.
* However, we need to ensure the following calculations.
*/
if ((div < min_div) || (div > max_div))
return -EINVAL;
/* Determine the first power of 2 greater than or equal to div */
if (div & (div - 1))
mbrdiv = fls(div);
else
mbrdiv = fls(div) - 1;
spi->cur_speed = spi->clk_rate / (1 << mbrdiv);
return mbrdiv - 1;
}
/**
* stm32h7_spi_prepare_fthlv - Determine FIFO threshold level
* @spi: pointer to the spi controller data structure
*/
static u32 stm32h7_spi_prepare_fthlv(struct stm32_spi *spi)
{
u32 fthlv, half_fifo;
/* data packet should not exceed 1/2 of fifo space */
half_fifo = (spi->fifo_size / 2);
if (spi->cur_bpw <= 8)
fthlv = half_fifo;
else if (spi->cur_bpw <= 16)
fthlv = half_fifo / 2;
else
fthlv = half_fifo / 4;
/* align packet size with data registers access */
if (spi->cur_bpw > 8)
fthlv -= (fthlv % 2); /* multiple of 2 */
else
fthlv -= (fthlv % 4); /* multiple of 4 */
return fthlv;
}
/**
* stm32f4_spi_write_tx - Write bytes to Transmit Data Register
* @spi: pointer to the spi controller data structure
*
* Read from tx_buf depends on remaining bytes to avoid to read beyond
* tx_buf end.
*/
static void stm32f4_spi_write_tx(struct stm32_spi *spi)
{
if ((spi->tx_len > 0) && (readl_relaxed(spi->base + STM32F4_SPI_SR) &
STM32F4_SPI_SR_TXE)) {
u32 offs = spi->cur_xferlen - spi->tx_len;
if (spi->cur_bpw == 16) {
const u16 *tx_buf16 = (const u16 *)(spi->tx_buf + offs);
writew_relaxed(*tx_buf16, spi->base + STM32F4_SPI_DR);
spi->tx_len -= sizeof(u16);
} else {
const u8 *tx_buf8 = (const u8 *)(spi->tx_buf + offs);
writeb_relaxed(*tx_buf8, spi->base + STM32F4_SPI_DR);
spi->tx_len -= sizeof(u8);
}
}
dev_dbg(spi->dev, "%s: %d bytes left\n", __func__, spi->tx_len);
}
/**
* stm32h7_spi_write_txfifo - Write bytes in Transmit Data Register
* @spi: pointer to the spi controller data structure
*
* Read from tx_buf depends on remaining bytes to avoid to read beyond
* tx_buf end.
*/
static void stm32h7_spi_write_txfifo(struct stm32_spi *spi)
{
while ((spi->tx_len > 0) &&
(readl_relaxed(spi->base + STM32H7_SPI_SR) &
STM32H7_SPI_SR_TXP)) {
u32 offs = spi->cur_xferlen - spi->tx_len;
if (spi->tx_len >= sizeof(u32)) {
const u32 *tx_buf32 = (const u32 *)(spi->tx_buf + offs);
writel_relaxed(*tx_buf32, spi->base + STM32H7_SPI_TXDR);
spi->tx_len -= sizeof(u32);
} else if (spi->tx_len >= sizeof(u16)) {
const u16 *tx_buf16 = (const u16 *)(spi->tx_buf + offs);
writew_relaxed(*tx_buf16, spi->base + STM32H7_SPI_TXDR);
spi->tx_len -= sizeof(u16);
} else {
const u8 *tx_buf8 = (const u8 *)(spi->tx_buf + offs);
writeb_relaxed(*tx_buf8, spi->base + STM32H7_SPI_TXDR);
spi->tx_len -= sizeof(u8);
}
}
dev_dbg(spi->dev, "%s: %d bytes left\n", __func__, spi->tx_len);
}
/**
* stm32f4_spi_read_rx - Read bytes from Receive Data Register
* @spi: pointer to the spi controller data structure
*
* Write in rx_buf depends on remaining bytes to avoid to write beyond
* rx_buf end.
*/
static void stm32f4_spi_read_rx(struct stm32_spi *spi)
{
if ((spi->rx_len > 0) && (readl_relaxed(spi->base + STM32F4_SPI_SR) &
STM32F4_SPI_SR_RXNE)) {
u32 offs = spi->cur_xferlen - spi->rx_len;
if (spi->cur_bpw == 16) {
u16 *rx_buf16 = (u16 *)(spi->rx_buf + offs);
*rx_buf16 = readw_relaxed(spi->base + STM32F4_SPI_DR);
spi->rx_len -= sizeof(u16);
} else {
u8 *rx_buf8 = (u8 *)(spi->rx_buf + offs);
*rx_buf8 = readb_relaxed(spi->base + STM32F4_SPI_DR);
spi->rx_len -= sizeof(u8);
}
}
dev_dbg(spi->dev, "%s: %d bytes left\n", __func__, spi->rx_len);
}
/**
* stm32h7_spi_read_rxfifo - Read bytes in Receive Data Register
* @spi: pointer to the spi controller data structure
*
* Write in rx_buf depends on remaining bytes to avoid to write beyond
* rx_buf end.
*/
static void stm32h7_spi_read_rxfifo(struct stm32_spi *spi, bool flush)
{
u32 sr = readl_relaxed(spi->base + STM32H7_SPI_SR);
u32 rxplvl = (sr & STM32H7_SPI_SR_RXPLVL) >>
STM32H7_SPI_SR_RXPLVL_SHIFT;
while ((spi->rx_len > 0) &&
((sr & STM32H7_SPI_SR_RXP) ||
(flush && ((sr & STM32H7_SPI_SR_RXWNE) || (rxplvl > 0))))) {
u32 offs = spi->cur_xferlen - spi->rx_len;
if ((spi->rx_len >= sizeof(u32)) ||
(flush && (sr & STM32H7_SPI_SR_RXWNE))) {
u32 *rx_buf32 = (u32 *)(spi->rx_buf + offs);
*rx_buf32 = readl_relaxed(spi->base + STM32H7_SPI_RXDR);
spi->rx_len -= sizeof(u32);
} else if ((spi->rx_len >= sizeof(u16)) ||
(flush && (rxplvl >= 2 || spi->cur_bpw > 8))) {
u16 *rx_buf16 = (u16 *)(spi->rx_buf + offs);
*rx_buf16 = readw_relaxed(spi->base + STM32H7_SPI_RXDR);
spi->rx_len -= sizeof(u16);
} else {
u8 *rx_buf8 = (u8 *)(spi->rx_buf + offs);
*rx_buf8 = readb_relaxed(spi->base + STM32H7_SPI_RXDR);
spi->rx_len -= sizeof(u8);
}
sr = readl_relaxed(spi->base + STM32H7_SPI_SR);
rxplvl = (sr & STM32H7_SPI_SR_RXPLVL) >>
STM32H7_SPI_SR_RXPLVL_SHIFT;
}
dev_dbg(spi->dev, "%s%s: %d bytes left\n", __func__,
flush ? "(flush)" : "", spi->rx_len);
}
/**
* stm32_spi_enable - Enable SPI controller
* @spi: pointer to the spi controller data structure
*/
static void stm32_spi_enable(struct stm32_spi *spi)
{
dev_dbg(spi->dev, "enable controller\n");
stm32_spi_set_bits(spi, spi->cfg->regs->en.reg,
spi->cfg->regs->en.mask);
}
/**
* stm32f4_spi_disable - Disable SPI controller
* @spi: pointer to the spi controller data structure
*/
static void stm32f4_spi_disable(struct stm32_spi *spi)
{
unsigned long flags;
u32 sr;
dev_dbg(spi->dev, "disable controller\n");
spin_lock_irqsave(&spi->lock, flags);
if (!(readl_relaxed(spi->base + STM32F4_SPI_CR1) &
STM32F4_SPI_CR1_SPE)) {
spin_unlock_irqrestore(&spi->lock, flags);
return;
}
/* Disable interrupts */
stm32_spi_clr_bits(spi, STM32F4_SPI_CR2, STM32F4_SPI_CR2_TXEIE |
STM32F4_SPI_CR2_RXNEIE |
STM32F4_SPI_CR2_ERRIE);
/* Wait until BSY = 0 */
if (readl_relaxed_poll_timeout_atomic(spi->base + STM32F4_SPI_SR,
sr, !(sr & STM32F4_SPI_SR_BSY),
10, 100000) < 0) {
dev_warn(spi->dev, "disabling condition timeout\n");
}
if (spi->cur_usedma && spi->dma_tx)
dmaengine_terminate_all(spi->dma_tx);
if (spi->cur_usedma && spi->dma_rx)
dmaengine_terminate_all(spi->dma_rx);
stm32_spi_clr_bits(spi, STM32F4_SPI_CR1, STM32F4_SPI_CR1_SPE);
stm32_spi_clr_bits(spi, STM32F4_SPI_CR2, STM32F4_SPI_CR2_TXDMAEN |
STM32F4_SPI_CR2_RXDMAEN);
/* Sequence to clear OVR flag */
readl_relaxed(spi->base + STM32F4_SPI_DR);
readl_relaxed(spi->base + STM32F4_SPI_SR);
spin_unlock_irqrestore(&spi->lock, flags);
}
/**
* stm32h7_spi_disable - Disable SPI controller
* @spi: pointer to the spi controller data structure
*
* RX-Fifo is flushed when SPI controller is disabled. To prevent any data
* loss, use stm32h7_spi_read_rxfifo(flush) to read the remaining bytes in
* RX-Fifo.
* Normally, if TSIZE has been configured, we should relax the hardware at the
* reception of the EOT interrupt. But in case of error, EOT will not be
* raised. So the subsystem unprepare_message call allows us to properly
* complete the transfer from an hardware point of view.
*/
static void stm32h7_spi_disable(struct stm32_spi *spi)
{
unsigned long flags;
u32 cr1, sr;
dev_dbg(spi->dev, "disable controller\n");
spin_lock_irqsave(&spi->lock, flags);
cr1 = readl_relaxed(spi->base + STM32H7_SPI_CR1);
if (!(cr1 & STM32H7_SPI_CR1_SPE)) {
spin_unlock_irqrestore(&spi->lock, flags);
return;
}
/* Wait on EOT or suspend the flow */
if (readl_relaxed_poll_timeout_atomic(spi->base + STM32H7_SPI_SR,
sr, !(sr & STM32H7_SPI_SR_EOT),
10, 100000) < 0) {
if (cr1 & STM32H7_SPI_CR1_CSTART) {
writel_relaxed(cr1 | STM32H7_SPI_CR1_CSUSP,
spi->base + STM32H7_SPI_CR1);
if (readl_relaxed_poll_timeout_atomic(
spi->base + STM32H7_SPI_SR,
sr, !(sr & STM32H7_SPI_SR_SUSP),
10, 100000) < 0)
dev_warn(spi->dev,
"Suspend request timeout\n");
}
}
if (!spi->cur_usedma && spi->rx_buf && (spi->rx_len > 0))
stm32h7_spi_read_rxfifo(spi, true);
if (spi->cur_usedma && spi->dma_tx)
dmaengine_terminate_all(spi->dma_tx);
if (spi->cur_usedma && spi->dma_rx)
dmaengine_terminate_all(spi->dma_rx);
stm32_spi_clr_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_SPE);
stm32_spi_clr_bits(spi, STM32H7_SPI_CFG1, STM32H7_SPI_CFG1_TXDMAEN |
STM32H7_SPI_CFG1_RXDMAEN);
/* Disable interrupts and clear status flags */
writel_relaxed(0, spi->base + STM32H7_SPI_IER);
writel_relaxed(STM32H7_SPI_IFCR_ALL, spi->base + STM32H7_SPI_IFCR);
spin_unlock_irqrestore(&spi->lock, flags);
}
/**
* stm32_spi_can_dma - Determine if the transfer is eligible for DMA use
*
* If driver has fifo and the current transfer size is greater than fifo size,
* use DMA. Otherwise use DMA for transfer longer than defined DMA min bytes.
*/
static bool stm32_spi_can_dma(struct spi_master *master,
struct spi_device *spi_dev,
struct spi_transfer *transfer)
{
unsigned int dma_size;
struct stm32_spi *spi = spi_master_get_devdata(master);
if (spi->cfg->has_fifo)
dma_size = spi->fifo_size;
else
dma_size = SPI_DMA_MIN_BYTES;
dev_dbg(spi->dev, "%s: %s\n", __func__,
(transfer->len > dma_size) ? "true" : "false");
return (transfer->len > dma_size);
}
/**
* stm32f4_spi_irq_event - Interrupt handler for SPI controller events
* @irq: interrupt line
* @dev_id: SPI controller master interface
*/
static irqreturn_t stm32f4_spi_irq_event(int irq, void *dev_id)
{
struct spi_master *master = dev_id;
struct stm32_spi *spi = spi_master_get_devdata(master);
u32 sr, mask = 0;
unsigned long flags;
bool end = false;
spin_lock_irqsave(&spi->lock, flags);
sr = readl_relaxed(spi->base + STM32F4_SPI_SR);
/*
* BSY flag is not handled in interrupt but it is normal behavior when
* this flag is set.
*/
sr &= ~STM32F4_SPI_SR_BSY;
if (!spi->cur_usedma && (spi->cur_comm == SPI_SIMPLEX_TX ||
spi->cur_comm == SPI_3WIRE_TX)) {
/* OVR flag shouldn't be handled for TX only mode */
sr &= ~STM32F4_SPI_SR_OVR | STM32F4_SPI_SR_RXNE;
mask |= STM32F4_SPI_SR_TXE;
}
if (!spi->cur_usedma && spi->cur_comm == SPI_FULL_DUPLEX) {
/* TXE flag is set and is handled when RXNE flag occurs */
sr &= ~STM32F4_SPI_SR_TXE;
mask |= STM32F4_SPI_SR_RXNE | STM32F4_SPI_SR_OVR;
}
if (!(sr & mask)) {
dev_dbg(spi->dev, "spurious IT (sr=0x%08x)\n", sr);
spin_unlock_irqrestore(&spi->lock, flags);
return IRQ_NONE;
}
if (sr & STM32F4_SPI_SR_OVR) {
dev_warn(spi->dev, "Overrun: received value discarded\n");
/* Sequence to clear OVR flag */
readl_relaxed(spi->base + STM32F4_SPI_DR);
readl_relaxed(spi->base + STM32F4_SPI_SR);
/*
* If overrun is detected, it means that something went wrong,
* so stop the current transfer. Transfer can wait for next
* RXNE but DR is already read and end never happens.
*/
end = true;
goto end_irq;
}
if (sr & STM32F4_SPI_SR_TXE) {
if (spi->tx_buf)
stm32f4_spi_write_tx(spi);
if (spi->tx_len == 0)
end = true;
}
if (sr & STM32F4_SPI_SR_RXNE) {
stm32f4_spi_read_rx(spi);
if (spi->rx_len == 0)
end = true;
else /* Load data for discontinuous mode */
stm32f4_spi_write_tx(spi);
}
end_irq:
if (end) {
/* Immediately disable interrupts to do not generate new one */
stm32_spi_clr_bits(spi, STM32F4_SPI_CR2,
STM32F4_SPI_CR2_TXEIE |
STM32F4_SPI_CR2_RXNEIE |
STM32F4_SPI_CR2_ERRIE);
spin_unlock_irqrestore(&spi->lock, flags);
return IRQ_WAKE_THREAD;
}
spin_unlock_irqrestore(&spi->lock, flags);
return IRQ_HANDLED;
}
/**
* stm32f4_spi_irq_thread - Thread of interrupt handler for SPI controller
* @irq: interrupt line
* @dev_id: SPI controller master interface
*/
static irqreturn_t stm32f4_spi_irq_thread(int irq, void *dev_id)
{
struct spi_master *master = dev_id;
struct stm32_spi *spi = spi_master_get_devdata(master);
spi_finalize_current_transfer(master);
stm32f4_spi_disable(spi);
return IRQ_HANDLED;
}
/**
* stm32h7_spi_irq_thread - Thread of interrupt handler for SPI controller
* @irq: interrupt line
* @dev_id: SPI controller master interface
*/
static irqreturn_t stm32h7_spi_irq_thread(int irq, void *dev_id)
{
struct spi_master *master = dev_id;
struct stm32_spi *spi = spi_master_get_devdata(master);
u32 sr, ier, mask;
unsigned long flags;
bool end = false;
spin_lock_irqsave(&spi->lock, flags);
sr = readl_relaxed(spi->base + STM32H7_SPI_SR);
ier = readl_relaxed(spi->base + STM32H7_SPI_IER);
mask = ier;
/* EOTIE is triggered on EOT, SUSP and TXC events. */
mask |= STM32H7_SPI_SR_SUSP;
/*
* When TXTF is set, DXPIE and TXPIE are cleared. So in case of
* Full-Duplex, need to poll RXP event to know if there are remaining
* data, before disabling SPI.
*/
if (spi->rx_buf && !spi->cur_usedma)
mask |= STM32H7_SPI_SR_RXP;
if (!(sr & mask)) {
dev_dbg(spi->dev, "spurious IT (sr=0x%08x, ier=0x%08x)\n",
sr, ier);
spin_unlock_irqrestore(&spi->lock, flags);
return IRQ_NONE;
}
if (sr & STM32H7_SPI_SR_SUSP) {
dev_warn(spi->dev, "Communication suspended\n");
if (!spi->cur_usedma && (spi->rx_buf && (spi->rx_len > 0)))
stm32h7_spi_read_rxfifo(spi, false);
/*
* If communication is suspended while using DMA, it means
* that something went wrong, so stop the current transfer
*/
if (spi->cur_usedma)
end = true;
}
if (sr & STM32H7_SPI_SR_MODF) {
dev_warn(spi->dev, "Mode fault: transfer aborted\n");
end = true;
}
if (sr & STM32H7_SPI_SR_OVR) {
dev_warn(spi->dev, "Overrun: received value discarded\n");
if (!spi->cur_usedma && (spi->rx_buf && (spi->rx_len > 0)))
stm32h7_spi_read_rxfifo(spi, false);
/*
* If overrun is detected while using DMA, it means that
* something went wrong, so stop the current transfer
*/
if (spi->cur_usedma)
end = true;
}
if (sr & STM32H7_SPI_SR_EOT) {
if (!spi->cur_usedma && (spi->rx_buf && (spi->rx_len > 0)))
stm32h7_spi_read_rxfifo(spi, true);
end = true;
}
if (sr & STM32H7_SPI_SR_TXP)
if (!spi->cur_usedma && (spi->tx_buf && (spi->tx_len > 0)))
stm32h7_spi_write_txfifo(spi);
if (sr & STM32H7_SPI_SR_RXP)
if (!spi->cur_usedma && (spi->rx_buf && (spi->rx_len > 0)))
stm32h7_spi_read_rxfifo(spi, false);
writel_relaxed(mask, spi->base + STM32H7_SPI_IFCR);
spin_unlock_irqrestore(&spi->lock, flags);
if (end) {
spi_finalize_current_transfer(master);
stm32h7_spi_disable(spi);
}
return IRQ_HANDLED;
}
/**
* stm32_spi_prepare_msg - set up the controller to transfer a single message
*/
static int stm32_spi_prepare_msg(struct spi_master *master,
struct spi_message *msg)
{
struct stm32_spi *spi = spi_master_get_devdata(master);
struct spi_device *spi_dev = msg->spi;
struct device_node *np = spi_dev->dev.of_node;
unsigned long flags;
u32 clrb = 0, setb = 0;
/* SPI slave device may need time between data frames */
spi->cur_midi = 0;
if (np && !of_property_read_u32(np, "st,spi-midi-ns", &spi->cur_midi))
dev_dbg(spi->dev, "%dns inter-data idleness\n", spi->cur_midi);
if (spi_dev->mode & SPI_CPOL)
setb |= spi->cfg->regs->cpol.mask;
else
clrb |= spi->cfg->regs->cpol.mask;
if (spi_dev->mode & SPI_CPHA)
setb |= spi->cfg->regs->cpha.mask;
else
clrb |= spi->cfg->regs->cpha.mask;
if (spi_dev->mode & SPI_LSB_FIRST)
setb |= spi->cfg->regs->lsb_first.mask;
else
clrb |= spi->cfg->regs->lsb_first.mask;
dev_dbg(spi->dev, "cpol=%d cpha=%d lsb_first=%d cs_high=%d\n",
spi_dev->mode & SPI_CPOL,
spi_dev->mode & SPI_CPHA,
spi_dev->mode & SPI_LSB_FIRST,
spi_dev->mode & SPI_CS_HIGH);
spin_lock_irqsave(&spi->lock, flags);
/* CPOL, CPHA and LSB FIRST bits have common register */
if (clrb || setb)
writel_relaxed(
(readl_relaxed(spi->base + spi->cfg->regs->cpol.reg) &
~clrb) | setb,
spi->base + spi->cfg->regs->cpol.reg);
spin_unlock_irqrestore(&spi->lock, flags);
return 0;
}
/**
* stm32f4_spi_dma_tx_cb - dma callback
*
* DMA callback is called when the transfer is complete for DMA TX channel.
*/
static void stm32f4_spi_dma_tx_cb(void *data)
{
struct stm32_spi *spi = data;
if (spi->cur_comm == SPI_SIMPLEX_TX || spi->cur_comm == SPI_3WIRE_TX) {
spi_finalize_current_transfer(spi->master);
stm32f4_spi_disable(spi);
}
}
/**
* stm32f4_spi_dma_rx_cb - dma callback
*
* DMA callback is called when the transfer is complete for DMA RX channel.
*/
static void stm32f4_spi_dma_rx_cb(void *data)
{
struct stm32_spi *spi = data;
spi_finalize_current_transfer(spi->master);
stm32f4_spi_disable(spi);
}
/**
* stm32h7_spi_dma_cb - dma callback
*
* DMA callback is called when the transfer is complete or when an error
* occurs. If the transfer is complete, EOT flag is raised.
*/
static void stm32h7_spi_dma_cb(void *data)
{
struct stm32_spi *spi = data;
unsigned long flags;
u32 sr;
spin_lock_irqsave(&spi->lock, flags);
sr = readl_relaxed(spi->base + STM32H7_SPI_SR);
spin_unlock_irqrestore(&spi->lock, flags);
if (!(sr & STM32H7_SPI_SR_EOT))
dev_warn(spi->dev, "DMA error (sr=0x%08x)\n", sr);
/* Now wait for EOT, or SUSP or OVR in case of error */
}
/**
* stm32_spi_dma_config - configure dma slave channel depending on current
* transfer bits_per_word.
*/
static void stm32_spi_dma_config(struct stm32_spi *spi,
struct dma_slave_config *dma_conf,
enum dma_transfer_direction dir)
{
enum dma_slave_buswidth buswidth;
u32 maxburst;
if (spi->cur_bpw <= 8)
buswidth = DMA_SLAVE_BUSWIDTH_1_BYTE;
else if (spi->cur_bpw <= 16)
buswidth = DMA_SLAVE_BUSWIDTH_2_BYTES;
else
buswidth = DMA_SLAVE_BUSWIDTH_4_BYTES;
if (spi->cfg->has_fifo) {
/* Valid for DMA Half or Full Fifo threshold */
if (spi->cur_fthlv == 2)
maxburst = 1;
else
maxburst = spi->cur_fthlv;
} else {
maxburst = 1;
}
memset(dma_conf, 0, sizeof(struct dma_slave_config));
dma_conf->direction = dir;
if (dma_conf->direction == DMA_DEV_TO_MEM) { /* RX */
dma_conf->src_addr = spi->phys_addr + spi->cfg->regs->rx.reg;
dma_conf->src_addr_width = buswidth;
dma_conf->src_maxburst = maxburst;
dev_dbg(spi->dev, "Rx DMA config buswidth=%d, maxburst=%d\n",
buswidth, maxburst);
} else if (dma_conf->direction == DMA_MEM_TO_DEV) { /* TX */
dma_conf->dst_addr = spi->phys_addr + spi->cfg->regs->tx.reg;
dma_conf->dst_addr_width = buswidth;
dma_conf->dst_maxburst = maxburst;
dev_dbg(spi->dev, "Tx DMA config buswidth=%d, maxburst=%d\n",
buswidth, maxburst);
}
}
/**
* stm32f4_spi_transfer_one_irq - transfer a single spi_transfer using
* interrupts
*
* It must returns 0 if the transfer is finished or 1 if the transfer is still
* in progress.
*/
static int stm32f4_spi_transfer_one_irq(struct stm32_spi *spi)
{
unsigned long flags;
u32 cr2 = 0;
/* Enable the interrupts relative to the current communication mode */
if (spi->cur_comm == SPI_SIMPLEX_TX || spi->cur_comm == SPI_3WIRE_TX) {
cr2 |= STM32F4_SPI_CR2_TXEIE;
} else if (spi->cur_comm == SPI_FULL_DUPLEX) {
/* In transmit-only mode, the OVR flag is set in the SR register
* since the received data are never read. Therefore set OVR
* interrupt only when rx buffer is available.
*/
cr2 |= STM32F4_SPI_CR2_RXNEIE | STM32F4_SPI_CR2_ERRIE;
} else {
return -EINVAL;
}
spin_lock_irqsave(&spi->lock, flags);
stm32_spi_set_bits(spi, STM32F4_SPI_CR2, cr2);
stm32_spi_enable(spi);
/* starting data transfer when buffer is loaded */
if (spi->tx_buf)
stm32f4_spi_write_tx(spi);
spin_unlock_irqrestore(&spi->lock, flags);
return 1;
}
/**
* stm32h7_spi_transfer_one_irq - transfer a single spi_transfer using
* interrupts
*
* It must returns 0 if the transfer is finished or 1 if the transfer is still
* in progress.
*/
static int stm32h7_spi_transfer_one_irq(struct stm32_spi *spi)
{
unsigned long flags;
u32 ier = 0;
/* Enable the interrupts relative to the current communication mode */
if (spi->tx_buf && spi->rx_buf) /* Full Duplex */
ier |= STM32H7_SPI_IER_DXPIE;
else if (spi->tx_buf) /* Half-Duplex TX dir or Simplex TX */
ier |= STM32H7_SPI_IER_TXPIE;
else if (spi->rx_buf) /* Half-Duplex RX dir or Simplex RX */
ier |= STM32H7_SPI_IER_RXPIE;
/* Enable the interrupts relative to the end of transfer */
ier |= STM32H7_SPI_IER_EOTIE | STM32H7_SPI_IER_TXTFIE |
STM32H7_SPI_IER_OVRIE | STM32H7_SPI_IER_MODFIE;
spin_lock_irqsave(&spi->lock, flags);
stm32_spi_enable(spi);
/* Be sure to have data in fifo before starting data transfer */
if (spi->tx_buf)
stm32h7_spi_write_txfifo(spi);
stm32_spi_set_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_CSTART);
writel_relaxed(ier, spi->base + STM32H7_SPI_IER);
spin_unlock_irqrestore(&spi->lock, flags);
return 1;
}
/**
* stm32f4_spi_transfer_one_dma_start - Set SPI driver registers to start
* transfer using DMA
*/
static void stm32f4_spi_transfer_one_dma_start(struct stm32_spi *spi)
{
/* In DMA mode end of transfer is handled by DMA TX or RX callback. */
if (spi->cur_comm == SPI_SIMPLEX_RX || spi->cur_comm == SPI_3WIRE_RX ||
spi->cur_comm == SPI_FULL_DUPLEX) {
/*
* In transmit-only mode, the OVR flag is set in the SR register
* since the received data are never read. Therefore set OVR
* interrupt only when rx buffer is available.
*/
stm32_spi_set_bits(spi, STM32F4_SPI_CR2, STM32F4_SPI_CR2_ERRIE);
}
stm32_spi_enable(spi);
}
/**
* stm32h7_spi_transfer_one_dma_start - Set SPI driver registers to start
* transfer using DMA
*/
static void stm32h7_spi_transfer_one_dma_start(struct stm32_spi *spi)
{
/* Enable the interrupts relative to the end of transfer */
stm32_spi_set_bits(spi, STM32H7_SPI_IER, STM32H7_SPI_IER_EOTIE |
STM32H7_SPI_IER_TXTFIE |
STM32H7_SPI_IER_OVRIE |
STM32H7_SPI_IER_MODFIE);
stm32_spi_enable(spi);
stm32_spi_set_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_CSTART);
}
/**
* stm32_spi_transfer_one_dma - transfer a single spi_transfer using DMA
*
* It must returns 0 if the transfer is finished or 1 if the transfer is still
* in progress.
*/
static int stm32_spi_transfer_one_dma(struct stm32_spi *spi,
struct spi_transfer *xfer)
{
struct dma_slave_config tx_dma_conf, rx_dma_conf;
struct dma_async_tx_descriptor *tx_dma_desc, *rx_dma_desc;
unsigned long flags;
spin_lock_irqsave(&spi->lock, flags);
rx_dma_desc = NULL;
if (spi->rx_buf && spi->dma_rx) {
stm32_spi_dma_config(spi, &rx_dma_conf, DMA_DEV_TO_MEM);
dmaengine_slave_config(spi->dma_rx, &rx_dma_conf);
/* Enable Rx DMA request */
stm32_spi_set_bits(spi, spi->cfg->regs->dma_rx_en.reg,
spi->cfg->regs->dma_rx_en.mask);
rx_dma_desc = dmaengine_prep_slave_sg(
spi->dma_rx, xfer->rx_sg.sgl,
xfer->rx_sg.nents,
rx_dma_conf.direction,
DMA_PREP_INTERRUPT);
}
tx_dma_desc = NULL;
if (spi->tx_buf && spi->dma_tx) {
stm32_spi_dma_config(spi, &tx_dma_conf, DMA_MEM_TO_DEV);
dmaengine_slave_config(spi->dma_tx, &tx_dma_conf);
tx_dma_desc = dmaengine_prep_slave_sg(
spi->dma_tx, xfer->tx_sg.sgl,
xfer->tx_sg.nents,
tx_dma_conf.direction,
DMA_PREP_INTERRUPT);
}
if ((spi->tx_buf && spi->dma_tx && !tx_dma_desc) ||
(spi->rx_buf && spi->dma_rx && !rx_dma_desc))
goto dma_desc_error;
if (spi->cur_comm == SPI_FULL_DUPLEX && (!tx_dma_desc || !rx_dma_desc))
goto dma_desc_error;
if (rx_dma_desc) {
rx_dma_desc->callback = spi->cfg->dma_rx_cb;
rx_dma_desc->callback_param = spi;
if (dma_submit_error(dmaengine_submit(rx_dma_desc))) {
dev_err(spi->dev, "Rx DMA submit failed\n");
goto dma_desc_error;
}
/* Enable Rx DMA channel */
dma_async_issue_pending(spi->dma_rx);
}
if (tx_dma_desc) {
if (spi->cur_comm == SPI_SIMPLEX_TX ||
spi->cur_comm == SPI_3WIRE_TX) {
tx_dma_desc->callback = spi->cfg->dma_tx_cb;
tx_dma_desc->callback_param = spi;
}
if (dma_submit_error(dmaengine_submit(tx_dma_desc))) {
dev_err(spi->dev, "Tx DMA submit failed\n");
goto dma_submit_error;
}
/* Enable Tx DMA channel */
dma_async_issue_pending(spi->dma_tx);
/* Enable Tx DMA request */
stm32_spi_set_bits(spi, spi->cfg->regs->dma_tx_en.reg,
spi->cfg->regs->dma_tx_en.mask);
}
spi->cfg->transfer_one_dma_start(spi);
spin_unlock_irqrestore(&spi->lock, flags);
return 1;
dma_submit_error:
if (spi->dma_rx)
dmaengine_terminate_all(spi->dma_rx);
dma_desc_error:
stm32_spi_clr_bits(spi, spi->cfg->regs->dma_rx_en.reg,
spi->cfg->regs->dma_rx_en.mask);
spin_unlock_irqrestore(&spi->lock, flags);
dev_info(spi->dev, "DMA issue: fall back to irq transfer\n");
spi->cur_usedma = false;
return spi->cfg->transfer_one_irq(spi);
}
/**
* stm32f4_spi_set_bpw - Configure bits per word
* @spi: pointer to the spi controller data structure
*/
static void stm32f4_spi_set_bpw(struct stm32_spi *spi)
{
if (spi->cur_bpw == 16)
stm32_spi_set_bits(spi, STM32F4_SPI_CR1, STM32F4_SPI_CR1_DFF);
else
stm32_spi_clr_bits(spi, STM32F4_SPI_CR1, STM32F4_SPI_CR1_DFF);
}
/**
* stm32h7_spi_set_bpw - configure bits per word
* @spi: pointer to the spi controller data structure
*/
static void stm32h7_spi_set_bpw(struct stm32_spi *spi)
{
u32 bpw, fthlv;
u32 cfg1_clrb = 0, cfg1_setb = 0;
bpw = spi->cur_bpw - 1;
cfg1_clrb |= STM32H7_SPI_CFG1_DSIZE;
cfg1_setb |= (bpw << STM32H7_SPI_CFG1_DSIZE_SHIFT) &
STM32H7_SPI_CFG1_DSIZE;
spi->cur_fthlv = stm32h7_spi_prepare_fthlv(spi);
fthlv = spi->cur_fthlv - 1;
cfg1_clrb |= STM32H7_SPI_CFG1_FTHLV;
cfg1_setb |= (fthlv << STM32H7_SPI_CFG1_FTHLV_SHIFT) &
STM32H7_SPI_CFG1_FTHLV;
writel_relaxed(
(readl_relaxed(spi->base + STM32H7_SPI_CFG1) &
~cfg1_clrb) | cfg1_setb,
spi->base + STM32H7_SPI_CFG1);
}
/**
* stm32_spi_set_mbr - Configure baud rate divisor in master mode
* @spi: pointer to the spi controller data structure
* @mbrdiv: baud rate divisor value
*/
static void stm32_spi_set_mbr(struct stm32_spi *spi, u32 mbrdiv)
{
u32 clrb = 0, setb = 0;
clrb |= spi->cfg->regs->br.mask;
setb |= ((u32)mbrdiv << spi->cfg->regs->br.shift) &
spi->cfg->regs->br.mask;
writel_relaxed((readl_relaxed(spi->base + spi->cfg->regs->br.reg) &
~clrb) | setb,
spi->base + spi->cfg->regs->br.reg);
}
/**
* stm32_spi_communication_type - return transfer communication type
* @spi_dev: pointer to the spi device
* transfer: pointer to spi transfer
*/
static unsigned int stm32_spi_communication_type(struct spi_device *spi_dev,
struct spi_transfer *transfer)
{
unsigned int type = SPI_FULL_DUPLEX;
if (spi_dev->mode & SPI_3WIRE) { /* MISO/MOSI signals shared */
/*
* SPI_3WIRE and xfer->tx_buf != NULL and xfer->rx_buf != NULL
* is forbidden and unvalidated by SPI subsystem so depending
* on the valid buffer, we can determine the direction of the
* transfer.
*/
if (!transfer->tx_buf)
type = SPI_3WIRE_RX;
else
type = SPI_3WIRE_TX;
} else {
if (!transfer->tx_buf)
type = SPI_SIMPLEX_RX;
else if (!transfer->rx_buf)
type = SPI_SIMPLEX_TX;
}
return type;
}
/**
* stm32f4_spi_set_mode - configure communication mode
* @spi: pointer to the spi controller data structure
* @comm_type: type of communication to configure
*/
static int stm32f4_spi_set_mode(struct stm32_spi *spi, unsigned int comm_type)
{
if (comm_type == SPI_3WIRE_TX || comm_type == SPI_SIMPLEX_TX) {
stm32_spi_set_bits(spi, STM32F4_SPI_CR1,
STM32F4_SPI_CR1_BIDIMODE |
STM32F4_SPI_CR1_BIDIOE);
} else if (comm_type == SPI_FULL_DUPLEX) {
stm32_spi_clr_bits(spi, STM32F4_SPI_CR1,
STM32F4_SPI_CR1_BIDIMODE |
STM32F4_SPI_CR1_BIDIOE);
} else {
return -EINVAL;
}
return 0;
}
/**
* stm32h7_spi_set_mode - configure communication mode
* @spi: pointer to the spi controller data structure
* @comm_type: type of communication to configure
*/
static int stm32h7_spi_set_mode(struct stm32_spi *spi, unsigned int comm_type)
{
u32 mode;
u32 cfg2_clrb = 0, cfg2_setb = 0;
if (comm_type == SPI_3WIRE_RX) {
mode = STM32H7_SPI_HALF_DUPLEX;
stm32_spi_clr_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_HDDIR);
} else if (comm_type == SPI_3WIRE_TX) {
mode = STM32H7_SPI_HALF_DUPLEX;
stm32_spi_set_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_HDDIR);
} else if (comm_type == SPI_SIMPLEX_RX) {
mode = STM32H7_SPI_SIMPLEX_RX;
} else if (comm_type == SPI_SIMPLEX_TX) {
mode = STM32H7_SPI_SIMPLEX_TX;
} else {
mode = STM32H7_SPI_FULL_DUPLEX;
}
cfg2_clrb |= STM32H7_SPI_CFG2_COMM;
cfg2_setb |= (mode << STM32H7_SPI_CFG2_COMM_SHIFT) &
STM32H7_SPI_CFG2_COMM;
writel_relaxed(
(readl_relaxed(spi->base + STM32H7_SPI_CFG2) &
~cfg2_clrb) | cfg2_setb,
spi->base + STM32H7_SPI_CFG2);
return 0;
}
/**
* stm32h7_spi_data_idleness - configure minimum time delay inserted between two
* consecutive data frames in master mode
* @spi: pointer to the spi controller data structure
* @len: transfer len
*/
static void stm32h7_spi_data_idleness(struct stm32_spi *spi, u32 len)
{
u32 cfg2_clrb = 0, cfg2_setb = 0;
cfg2_clrb |= STM32H7_SPI_CFG2_MIDI;
if ((len > 1) && (spi->cur_midi > 0)) {
u32 sck_period_ns = DIV_ROUND_UP(SPI_1HZ_NS, spi->cur_speed);
u32 midi = min((u32)DIV_ROUND_UP(spi->cur_midi, sck_period_ns),
(u32)STM32H7_SPI_CFG2_MIDI >>
STM32H7_SPI_CFG2_MIDI_SHIFT);
dev_dbg(spi->dev, "period=%dns, midi=%d(=%dns)\n",
sck_period_ns, midi, midi * sck_period_ns);
cfg2_setb |= (midi << STM32H7_SPI_CFG2_MIDI_SHIFT) &
STM32H7_SPI_CFG2_MIDI;
}
writel_relaxed((readl_relaxed(spi->base + STM32H7_SPI_CFG2) &
~cfg2_clrb) | cfg2_setb,
spi->base + STM32H7_SPI_CFG2);
}
/**
* stm32h7_spi_number_of_data - configure number of data at current transfer
* @spi: pointer to the spi controller data structure
* @len: transfer length
*/
static int stm32h7_spi_number_of_data(struct stm32_spi *spi, u32 nb_words)
{
u32 cr2_clrb = 0, cr2_setb = 0;
if (nb_words <= (STM32H7_SPI_CR2_TSIZE >>
STM32H7_SPI_CR2_TSIZE_SHIFT)) {
cr2_clrb |= STM32H7_SPI_CR2_TSIZE;
cr2_setb = nb_words << STM32H7_SPI_CR2_TSIZE_SHIFT;
writel_relaxed((readl_relaxed(spi->base + STM32H7_SPI_CR2) &
~cr2_clrb) | cr2_setb,
spi->base + STM32H7_SPI_CR2);
} else {
return -EMSGSIZE;
}
return 0;
}
/**
* stm32_spi_transfer_one_setup - common setup to transfer a single
* spi_transfer either using DMA or
* interrupts.
*/
static int stm32_spi_transfer_one_setup(struct stm32_spi *spi,
struct spi_device *spi_dev,
struct spi_transfer *transfer)
{
unsigned long flags;
unsigned int comm_type;
int nb_words, ret = 0;
spin_lock_irqsave(&spi->lock, flags);
if (spi->cur_bpw != transfer->bits_per_word) {
spi->cur_bpw = transfer->bits_per_word;
spi->cfg->set_bpw(spi);
}
if (spi->cur_speed != transfer->speed_hz) {
int mbr;
/* Update spi->cur_speed with real clock speed */
mbr = stm32_spi_prepare_mbr(spi, transfer->speed_hz,
spi->cfg->baud_rate_div_min,
spi->cfg->baud_rate_div_max);
if (mbr < 0) {
ret = mbr;
goto out;
}
transfer->speed_hz = spi->cur_speed;
stm32_spi_set_mbr(spi, mbr);
}
comm_type = stm32_spi_communication_type(spi_dev, transfer);
if (spi->cur_comm != comm_type) {
ret = spi->cfg->set_mode(spi, comm_type);
if (ret < 0)
goto out;
spi->cur_comm = comm_type;
}
if (spi->cfg->set_data_idleness)
spi->cfg->set_data_idleness(spi, transfer->len);
if (spi->cur_bpw <= 8)
nb_words = transfer->len;
else if (spi->cur_bpw <= 16)
nb_words = DIV_ROUND_UP(transfer->len * 8, 16);
else
nb_words = DIV_ROUND_UP(transfer->len * 8, 32);
if (spi->cfg->set_number_of_data) {
ret = spi->cfg->set_number_of_data(spi, nb_words);
if (ret < 0)
goto out;
}
spi->cur_xferlen = transfer->len;
dev_dbg(spi->dev, "transfer communication mode set to %d\n",
spi->cur_comm);
dev_dbg(spi->dev,
"data frame of %d-bit, data packet of %d data frames\n",
spi->cur_bpw, spi->cur_fthlv);
dev_dbg(spi->dev, "speed set to %dHz\n", spi->cur_speed);
dev_dbg(spi->dev, "transfer of %d bytes (%d data frames)\n",
spi->cur_xferlen, nb_words);
dev_dbg(spi->dev, "dma %s\n",
(spi->cur_usedma) ? "enabled" : "disabled");
out:
spin_unlock_irqrestore(&spi->lock, flags);
return ret;
}
/**
* stm32_spi_transfer_one - transfer a single spi_transfer
*
* It must return 0 if the transfer is finished or 1 if the transfer is still
* in progress.
*/
static int stm32_spi_transfer_one(struct spi_master *master,
struct spi_device *spi_dev,
struct spi_transfer *transfer)
{
struct stm32_spi *spi = spi_master_get_devdata(master);
int ret;
spi->tx_buf = transfer->tx_buf;
spi->rx_buf = transfer->rx_buf;
spi->tx_len = spi->tx_buf ? transfer->len : 0;
spi->rx_len = spi->rx_buf ? transfer->len : 0;
spi->cur_usedma = (master->can_dma &&
master->can_dma(master, spi_dev, transfer));
ret = stm32_spi_transfer_one_setup(spi, spi_dev, transfer);
if (ret) {
dev_err(spi->dev, "SPI transfer setup failed\n");
return ret;
}
if (spi->cur_usedma)
return stm32_spi_transfer_one_dma(spi, transfer);
else
return spi->cfg->transfer_one_irq(spi);
}
/**
* stm32_spi_unprepare_msg - relax the hardware
*/
static int stm32_spi_unprepare_msg(struct spi_master *master,
struct spi_message *msg)
{
struct stm32_spi *spi = spi_master_get_devdata(master);
spi->cfg->disable(spi);
return 0;
}
/**
* stm32f4_spi_config - Configure SPI controller as SPI master
*/
static int stm32f4_spi_config(struct stm32_spi *spi)
{
unsigned long flags;
spin_lock_irqsave(&spi->lock, flags);
/* Ensure I2SMOD bit is kept cleared */
stm32_spi_clr_bits(spi, STM32F4_SPI_I2SCFGR,
STM32F4_SPI_I2SCFGR_I2SMOD);
/*
* - SS input value high
* - transmitter half duplex direction
* - Set the master mode (default Motorola mode)
* - Consider 1 master/n slaves configuration and
* SS input value is determined by the SSI bit
*/
stm32_spi_set_bits(spi, STM32F4_SPI_CR1, STM32F4_SPI_CR1_SSI |
STM32F4_SPI_CR1_BIDIOE |
STM32F4_SPI_CR1_MSTR |
STM32F4_SPI_CR1_SSM);
spin_unlock_irqrestore(&spi->lock, flags);
return 0;
}
/**
* stm32h7_spi_config - Configure SPI controller as SPI master
*/
static int stm32h7_spi_config(struct stm32_spi *spi)
{
unsigned long flags;
spin_lock_irqsave(&spi->lock, flags);
/* Ensure I2SMOD bit is kept cleared */
stm32_spi_clr_bits(spi, STM32H7_SPI_I2SCFGR,
STM32H7_SPI_I2SCFGR_I2SMOD);
/*
* - SS input value high
* - transmitter half duplex direction
* - automatic communication suspend when RX-Fifo is full
*/
stm32_spi_set_bits(spi, STM32H7_SPI_CR1, STM32H7_SPI_CR1_SSI |
STM32H7_SPI_CR1_HDDIR |
STM32H7_SPI_CR1_MASRX);
/*
* - Set the master mode (default Motorola mode)
* - Consider 1 master/n slaves configuration and
* SS input value is determined by the SSI bit
* - keep control of all associated GPIOs
*/
stm32_spi_set_bits(spi, STM32H7_SPI_CFG2, STM32H7_SPI_CFG2_MASTER |
STM32H7_SPI_CFG2_SSM |
STM32H7_SPI_CFG2_AFCNTR);
spin_unlock_irqrestore(&spi->lock, flags);
return 0;
}
static const struct stm32_spi_cfg stm32f4_spi_cfg = {
.regs = &stm32f4_spi_regspec,
.get_bpw_mask = stm32f4_spi_get_bpw_mask,
.disable = stm32f4_spi_disable,
.config = stm32f4_spi_config,
.set_bpw = stm32f4_spi_set_bpw,
.set_mode = stm32f4_spi_set_mode,
.transfer_one_dma_start = stm32f4_spi_transfer_one_dma_start,
.dma_tx_cb = stm32f4_spi_dma_tx_cb,
.dma_rx_cb = stm32f4_spi_dma_rx_cb,
.transfer_one_irq = stm32f4_spi_transfer_one_irq,
.irq_handler_event = stm32f4_spi_irq_event,
.irq_handler_thread = stm32f4_spi_irq_thread,
.baud_rate_div_min = STM32F4_SPI_BR_DIV_MIN,
.baud_rate_div_max = STM32F4_SPI_BR_DIV_MAX,
.has_fifo = false,
};
static const struct stm32_spi_cfg stm32h7_spi_cfg = {
.regs = &stm32h7_spi_regspec,
.get_fifo_size = stm32h7_spi_get_fifo_size,
.get_bpw_mask = stm32h7_spi_get_bpw_mask,
.disable = stm32h7_spi_disable,
.config = stm32h7_spi_config,
.set_bpw = stm32h7_spi_set_bpw,
.set_mode = stm32h7_spi_set_mode,
.set_data_idleness = stm32h7_spi_data_idleness,
.set_number_of_data = stm32h7_spi_number_of_data,
.transfer_one_dma_start = stm32h7_spi_transfer_one_dma_start,
.dma_rx_cb = stm32h7_spi_dma_cb,
.dma_tx_cb = stm32h7_spi_dma_cb,
.transfer_one_irq = stm32h7_spi_transfer_one_irq,
.irq_handler_thread = stm32h7_spi_irq_thread,
.baud_rate_div_min = STM32H7_SPI_MBR_DIV_MIN,
.baud_rate_div_max = STM32H7_SPI_MBR_DIV_MAX,
.has_fifo = true,
};
static const struct of_device_id stm32_spi_of_match[] = {
{ .compatible = "st,stm32h7-spi", .data = (void *)&stm32h7_spi_cfg },
{ .compatible = "st,stm32f4-spi", .data = (void *)&stm32f4_spi_cfg },
{},
};
MODULE_DEVICE_TABLE(of, stm32_spi_of_match);
static int stm32_spi_probe(struct platform_device *pdev)
{
struct spi_master *master;
struct stm32_spi *spi;
struct resource *res;
int ret;
master = spi_alloc_master(&pdev->dev, sizeof(struct stm32_spi));
if (!master) {
dev_err(&pdev->dev, "spi master allocation failed\n");
return -ENOMEM;
}
platform_set_drvdata(pdev, master);
spi = spi_master_get_devdata(master);
spi->dev = &pdev->dev;
spi->master = master;
spin_lock_init(&spi->lock);
spi->cfg = (const struct stm32_spi_cfg *)
of_match_device(pdev->dev.driver->of_match_table,
&pdev->dev)->data;
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
spi->base = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(spi->base)) {
ret = PTR_ERR(spi->base);
goto err_master_put;
}
spi->phys_addr = (dma_addr_t)res->start;
spi->irq = platform_get_irq(pdev, 0);
if (spi->irq <= 0) {
ret = spi->irq;
if (ret != -EPROBE_DEFER)
dev_err(&pdev->dev, "failed to get irq: %d\n", ret);
goto err_master_put;
}
ret = devm_request_threaded_irq(&pdev->dev, spi->irq,
spi->cfg->irq_handler_event,
spi->cfg->irq_handler_thread,
IRQF_ONESHOT, pdev->name, master);
if (ret) {
dev_err(&pdev->dev, "irq%d request failed: %d\n", spi->irq,
ret);
goto err_master_put;
}
spi->clk = devm_clk_get(&pdev->dev, NULL);
if (IS_ERR(spi->clk)) {
ret = PTR_ERR(spi->clk);
dev_err(&pdev->dev, "clk get failed: %d\n", ret);
goto err_master_put;
}
ret = clk_prepare_enable(spi->clk);
if (ret) {
dev_err(&pdev->dev, "clk enable failed: %d\n", ret);
goto err_master_put;
}
spi->clk_rate = clk_get_rate(spi->clk);
if (!spi->clk_rate) {
dev_err(&pdev->dev, "clk rate = 0\n");
ret = -EINVAL;
goto err_clk_disable;
}
spi->rst = devm_reset_control_get_exclusive(&pdev->dev, NULL);
if (!IS_ERR(spi->rst)) {
reset_control_assert(spi->rst);
udelay(2);
reset_control_deassert(spi->rst);
}
if (spi->cfg->has_fifo)
spi->fifo_size = spi->cfg->get_fifo_size(spi);
ret = spi->cfg->config(spi);
if (ret) {
dev_err(&pdev->dev, "controller configuration failed: %d\n",
ret);
goto err_clk_disable;
}
master->dev.of_node = pdev->dev.of_node;
master->auto_runtime_pm = true;
master->bus_num = pdev->id;
master->mode_bits = SPI_CPHA | SPI_CPOL | SPI_CS_HIGH | SPI_LSB_FIRST |
SPI_3WIRE;
master->bits_per_word_mask = spi->cfg->get_bpw_mask(spi);
master->max_speed_hz = spi->clk_rate / spi->cfg->baud_rate_div_min;
master->min_speed_hz = spi->clk_rate / spi->cfg->baud_rate_div_max;
master->use_gpio_descriptors = true;
master->prepare_message = stm32_spi_prepare_msg;
master->transfer_one = stm32_spi_transfer_one;
master->unprepare_message = stm32_spi_unprepare_msg;
spi->dma_tx = dma_request_slave_channel(spi->dev, "tx");
if (!spi->dma_tx)
dev_warn(&pdev->dev, "failed to request tx dma channel\n");
else
master->dma_tx = spi->dma_tx;
spi->dma_rx = dma_request_slave_channel(spi->dev, "rx");
if (!spi->dma_rx)
dev_warn(&pdev->dev, "failed to request rx dma channel\n");
else
master->dma_rx = spi->dma_rx;
if (spi->dma_tx || spi->dma_rx)
master->can_dma = stm32_spi_can_dma;
pm_runtime_set_active(&pdev->dev);
pm_runtime_enable(&pdev->dev);
ret = devm_spi_register_master(&pdev->dev, master);
if (ret) {
dev_err(&pdev->dev, "spi master registration failed: %d\n",
ret);
goto err_dma_release;
}
if (!master->cs_gpiods) {
dev_err(&pdev->dev, "no CS gpios available\n");
ret = -EINVAL;
goto err_dma_release;
}
dev_info(&pdev->dev, "driver initialized\n");
return 0;
err_dma_release:
if (spi->dma_tx)
dma_release_channel(spi->dma_tx);
if (spi->dma_rx)
dma_release_channel(spi->dma_rx);
pm_runtime_disable(&pdev->dev);
err_clk_disable:
clk_disable_unprepare(spi->clk);
err_master_put:
spi_master_put(master);
return ret;
}
static int stm32_spi_remove(struct platform_device *pdev)
{
struct spi_master *master = platform_get_drvdata(pdev);
struct stm32_spi *spi = spi_master_get_devdata(master);
spi->cfg->disable(spi);
if (master->dma_tx)
dma_release_channel(master->dma_tx);
if (master->dma_rx)
dma_release_channel(master->dma_rx);
clk_disable_unprepare(spi->clk);
pm_runtime_disable(&pdev->dev);
return 0;
}
#ifdef CONFIG_PM
static int stm32_spi_runtime_suspend(struct device *dev)
{
struct spi_master *master = dev_get_drvdata(dev);
struct stm32_spi *spi = spi_master_get_devdata(master);
clk_disable_unprepare(spi->clk);
return 0;
}
static int stm32_spi_runtime_resume(struct device *dev)
{
struct spi_master *master = dev_get_drvdata(dev);
struct stm32_spi *spi = spi_master_get_devdata(master);
return clk_prepare_enable(spi->clk);
}
#endif
#ifdef CONFIG_PM_SLEEP
static int stm32_spi_suspend(struct device *dev)
{
struct spi_master *master = dev_get_drvdata(dev);
int ret;
ret = spi_master_suspend(master);
if (ret)
return ret;
return pm_runtime_force_suspend(dev);
}
static int stm32_spi_resume(struct device *dev)
{
struct spi_master *master = dev_get_drvdata(dev);
struct stm32_spi *spi = spi_master_get_devdata(master);
int ret;
ret = pm_runtime_force_resume(dev);
if (ret)
return ret;
ret = spi_master_resume(master);
if (ret)
clk_disable_unprepare(spi->clk);
return ret;
}
#endif
static const struct dev_pm_ops stm32_spi_pm_ops = {
SET_SYSTEM_SLEEP_PM_OPS(stm32_spi_suspend, stm32_spi_resume)
SET_RUNTIME_PM_OPS(stm32_spi_runtime_suspend,
stm32_spi_runtime_resume, NULL)
};
static struct platform_driver stm32_spi_driver = {
.probe = stm32_spi_probe,
.remove = stm32_spi_remove,
.driver = {
.name = DRIVER_NAME,
.pm = &stm32_spi_pm_ops,
.of_match_table = stm32_spi_of_match,
},
};
module_platform_driver(stm32_spi_driver);
MODULE_ALIAS("platform:" DRIVER_NAME);
MODULE_DESCRIPTION("STMicroelectronics STM32 SPI Controller driver");
MODULE_AUTHOR("Amelie Delaunay <amelie.delaunay@st.com>");
MODULE_LICENSE("GPL v2");