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// SPDX-License-Identifier: GPL-2.0
// Copyright (C) 2018 Spreadtrum Communications Inc.
# include <linux/clk.h>
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# include <linux/dmaengine.h>
# include <linux/dma-mapping.h>
# include <linux/dma/sprd-dma.h>
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# include <linux/interrupt.h>
# include <linux/io.h>
# include <linux/iopoll.h>
# include <linux/kernel.h>
# include <linux/module.h>
# include <linux/of.h>
# include <linux/of_device.h>
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# include <linux/of_dma.h>
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# include <linux/platform_device.h>
# include <linux/pm_runtime.h>
# include <linux/spi/spi.h>
# define SPRD_SPI_TXD 0x0
# define SPRD_SPI_CLKD 0x4
# define SPRD_SPI_CTL0 0x8
# define SPRD_SPI_CTL1 0xc
# define SPRD_SPI_CTL2 0x10
# define SPRD_SPI_CTL3 0x14
# define SPRD_SPI_CTL4 0x18
# define SPRD_SPI_CTL5 0x1c
# define SPRD_SPI_INT_EN 0x20
# define SPRD_SPI_INT_CLR 0x24
# define SPRD_SPI_INT_RAW_STS 0x28
# define SPRD_SPI_INT_MASK_STS 0x2c
# define SPRD_SPI_STS1 0x30
# define SPRD_SPI_STS2 0x34
# define SPRD_SPI_DSP_WAIT 0x38
# define SPRD_SPI_STS3 0x3c
# define SPRD_SPI_CTL6 0x40
# define SPRD_SPI_STS4 0x44
# define SPRD_SPI_FIFO_RST 0x48
# define SPRD_SPI_CTL7 0x4c
# define SPRD_SPI_STS5 0x50
# define SPRD_SPI_CTL8 0x54
# define SPRD_SPI_CTL9 0x58
# define SPRD_SPI_CTL10 0x5c
# define SPRD_SPI_CTL11 0x60
# define SPRD_SPI_CTL12 0x64
# define SPRD_SPI_STS6 0x68
# define SPRD_SPI_STS7 0x6c
# define SPRD_SPI_STS8 0x70
# define SPRD_SPI_STS9 0x74
/* Bits & mask definition for register CTL0 */
# define SPRD_SPI_SCK_REV BIT(13)
# define SPRD_SPI_NG_TX BIT(1)
# define SPRD_SPI_NG_RX BIT(0)
# define SPRD_SPI_CHNL_LEN_MASK GENMASK(4, 0)
# define SPRD_SPI_CSN_MASK GENMASK(11, 8)
# define SPRD_SPI_CS0_VALID BIT(8)
/* Bits & mask definition for register SPI_INT_EN */
# define SPRD_SPI_TX_END_INT_EN BIT(8)
# define SPRD_SPI_RX_END_INT_EN BIT(9)
/* Bits & mask definition for register SPI_INT_RAW_STS */
# define SPRD_SPI_TX_END_RAW BIT(8)
# define SPRD_SPI_RX_END_RAW BIT(9)
/* Bits & mask definition for register SPI_INT_CLR */
# define SPRD_SPI_TX_END_CLR BIT(8)
# define SPRD_SPI_RX_END_CLR BIT(9)
/* Bits & mask definition for register INT_MASK_STS */
# define SPRD_SPI_MASK_RX_END BIT(9)
# define SPRD_SPI_MASK_TX_END BIT(8)
/* Bits & mask definition for register STS2 */
# define SPRD_SPI_TX_BUSY BIT(8)
/* Bits & mask definition for register CTL1 */
# define SPRD_SPI_RX_MODE BIT(12)
# define SPRD_SPI_TX_MODE BIT(13)
# define SPRD_SPI_RTX_MD_MASK GENMASK(13, 12)
/* Bits & mask definition for register CTL2 */
# define SPRD_SPI_DMA_EN BIT(6)
/* Bits & mask definition for register CTL4 */
# define SPRD_SPI_START_RX BIT(9)
# define SPRD_SPI_ONLY_RECV_MASK GENMASK(8, 0)
/* Bits & mask definition for register SPI_INT_CLR */
# define SPRD_SPI_RX_END_INT_CLR BIT(9)
# define SPRD_SPI_TX_END_INT_CLR BIT(8)
/* Bits & mask definition for register SPI_INT_RAW */
# define SPRD_SPI_RX_END_IRQ BIT(9)
# define SPRD_SPI_TX_END_IRQ BIT(8)
/* Bits & mask definition for register CTL12 */
# define SPRD_SPI_SW_RX_REQ BIT(0)
# define SPRD_SPI_SW_TX_REQ BIT(1)
/* Bits & mask definition for register CTL7 */
# define SPRD_SPI_DATA_LINE2_EN BIT(15)
# define SPRD_SPI_MODE_MASK GENMASK(5, 3)
# define SPRD_SPI_MODE_OFFSET 3
# define SPRD_SPI_3WIRE_MODE 4
# define SPRD_SPI_4WIRE_MODE 0
/* Bits & mask definition for register CTL8 */
# define SPRD_SPI_TX_MAX_LEN_MASK GENMASK(19, 0)
# define SPRD_SPI_TX_LEN_H_MASK GENMASK(3, 0)
# define SPRD_SPI_TX_LEN_H_OFFSET 16
/* Bits & mask definition for register CTL9 */
# define SPRD_SPI_TX_LEN_L_MASK GENMASK(15, 0)
/* Bits & mask definition for register CTL10 */
# define SPRD_SPI_RX_MAX_LEN_MASK GENMASK(19, 0)
# define SPRD_SPI_RX_LEN_H_MASK GENMASK(3, 0)
# define SPRD_SPI_RX_LEN_H_OFFSET 16
/* Bits & mask definition for register CTL11 */
# define SPRD_SPI_RX_LEN_L_MASK GENMASK(15, 0)
/* Default & maximum word delay cycles */
# define SPRD_SPI_MIN_DELAY_CYCLE 14
# define SPRD_SPI_MAX_DELAY_CYCLE 130
# define SPRD_SPI_FIFO_SIZE 32
# define SPRD_SPI_CHIP_CS_NUM 0x4
# define SPRD_SPI_CHNL_LEN 2
# define SPRD_SPI_DEFAULT_SOURCE 26000000
# define SPRD_SPI_MAX_SPEED_HZ 48000000
# define SPRD_SPI_AUTOSUSPEND_DELAY 100
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# define SPRD_SPI_DMA_STEP 8
enum sprd_spi_dma_channel {
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SPRD_SPI_RX ,
SPRD_SPI_TX ,
SPRD_SPI_MAX ,
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} ;
struct sprd_spi_dma {
bool enable ;
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struct dma_chan * dma_chan [ SPRD_SPI_MAX ] ;
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enum dma_slave_buswidth width ;
u32 fragmens_len ;
u32 rx_len ;
} ;
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struct sprd_spi {
void __iomem * base ;
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phys_addr_t phy_base ;
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struct device * dev ;
struct clk * clk ;
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int irq ;
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u32 src_clk ;
u32 hw_mode ;
u32 trans_len ;
u32 trans_mode ;
u32 word_delay ;
u32 hw_speed_hz ;
u32 len ;
int status ;
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struct sprd_spi_dma dma ;
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struct completion xfer_completion ;
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const void * tx_buf ;
void * rx_buf ;
int ( * read_bufs ) ( struct sprd_spi * ss , u32 len ) ;
int ( * write_bufs ) ( struct sprd_spi * ss , u32 len ) ;
} ;
static u32 sprd_spi_transfer_max_timeout ( struct sprd_spi * ss ,
struct spi_transfer * t )
{
/*
* The time spent on transmission of the full FIFO data is the maximum
* SPI transmission time .
*/
u32 size = t - > bits_per_word * SPRD_SPI_FIFO_SIZE ;
u32 bit_time_us = DIV_ROUND_UP ( USEC_PER_SEC , ss - > hw_speed_hz ) ;
u32 total_time_us = size * bit_time_us ;
/*
* There is an interval between data and the data in our SPI hardware ,
* so the total transmission time need add the interval time .
*/
u32 interval_cycle = SPRD_SPI_FIFO_SIZE * ss - > word_delay ;
u32 interval_time_us = DIV_ROUND_UP ( interval_cycle * USEC_PER_SEC ,
ss - > src_clk ) ;
return total_time_us + interval_time_us ;
}
static int sprd_spi_wait_for_tx_end ( struct sprd_spi * ss , struct spi_transfer * t )
{
u32 val , us ;
int ret ;
us = sprd_spi_transfer_max_timeout ( ss , t ) ;
ret = readl_relaxed_poll_timeout ( ss - > base + SPRD_SPI_INT_RAW_STS , val ,
val & SPRD_SPI_TX_END_IRQ , 0 , us ) ;
if ( ret ) {
dev_err ( ss - > dev , " SPI error, spi send timeout! \n " ) ;
return ret ;
}
ret = readl_relaxed_poll_timeout ( ss - > base + SPRD_SPI_STS2 , val ,
! ( val & SPRD_SPI_TX_BUSY ) , 0 , us ) ;
if ( ret ) {
dev_err ( ss - > dev , " SPI error, spi busy timeout! \n " ) ;
return ret ;
}
writel_relaxed ( SPRD_SPI_TX_END_INT_CLR , ss - > base + SPRD_SPI_INT_CLR ) ;
return 0 ;
}
static int sprd_spi_wait_for_rx_end ( struct sprd_spi * ss , struct spi_transfer * t )
{
u32 val , us ;
int ret ;
us = sprd_spi_transfer_max_timeout ( ss , t ) ;
ret = readl_relaxed_poll_timeout ( ss - > base + SPRD_SPI_INT_RAW_STS , val ,
val & SPRD_SPI_RX_END_IRQ , 0 , us ) ;
if ( ret ) {
dev_err ( ss - > dev , " SPI error, spi rx timeout! \n " ) ;
return ret ;
}
writel_relaxed ( SPRD_SPI_RX_END_INT_CLR , ss - > base + SPRD_SPI_INT_CLR ) ;
return 0 ;
}
static void sprd_spi_tx_req ( struct sprd_spi * ss )
{
writel_relaxed ( SPRD_SPI_SW_TX_REQ , ss - > base + SPRD_SPI_CTL12 ) ;
}
static void sprd_spi_rx_req ( struct sprd_spi * ss )
{
writel_relaxed ( SPRD_SPI_SW_RX_REQ , ss - > base + SPRD_SPI_CTL12 ) ;
}
static void sprd_spi_enter_idle ( struct sprd_spi * ss )
{
u32 val = readl_relaxed ( ss - > base + SPRD_SPI_CTL1 ) ;
val & = ~ SPRD_SPI_RTX_MD_MASK ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL1 ) ;
}
static void sprd_spi_set_transfer_bits ( struct sprd_spi * ss , u32 bits )
{
u32 val = readl_relaxed ( ss - > base + SPRD_SPI_CTL0 ) ;
/* Set the valid bits for every transaction */
val & = ~ ( SPRD_SPI_CHNL_LEN_MASK < < SPRD_SPI_CHNL_LEN ) ;
val | = bits < < SPRD_SPI_CHNL_LEN ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL0 ) ;
}
static void sprd_spi_set_tx_length ( struct sprd_spi * ss , u32 length )
{
u32 val = readl_relaxed ( ss - > base + SPRD_SPI_CTL8 ) ;
length & = SPRD_SPI_TX_MAX_LEN_MASK ;
val & = ~ SPRD_SPI_TX_LEN_H_MASK ;
val | = length > > SPRD_SPI_TX_LEN_H_OFFSET ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL8 ) ;
val = length & SPRD_SPI_TX_LEN_L_MASK ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL9 ) ;
}
static void sprd_spi_set_rx_length ( struct sprd_spi * ss , u32 length )
{
u32 val = readl_relaxed ( ss - > base + SPRD_SPI_CTL10 ) ;
length & = SPRD_SPI_RX_MAX_LEN_MASK ;
val & = ~ SPRD_SPI_RX_LEN_H_MASK ;
val | = length > > SPRD_SPI_RX_LEN_H_OFFSET ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL10 ) ;
val = length & SPRD_SPI_RX_LEN_L_MASK ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL11 ) ;
}
static void sprd_spi_chipselect ( struct spi_device * sdev , bool cs )
{
struct spi_controller * sctlr = sdev - > controller ;
struct sprd_spi * ss = spi_controller_get_devdata ( sctlr ) ;
u32 val ;
val = readl_relaxed ( ss - > base + SPRD_SPI_CTL0 ) ;
/* The SPI controller will pull down CS pin if cs is 0 */
if ( ! cs ) {
val & = ~ SPRD_SPI_CS0_VALID ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL0 ) ;
} else {
val | = SPRD_SPI_CSN_MASK ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL0 ) ;
}
}
static int sprd_spi_write_only_receive ( struct sprd_spi * ss , u32 len )
{
u32 val ;
/* Clear the start receive bit and reset receive data number */
val = readl_relaxed ( ss - > base + SPRD_SPI_CTL4 ) ;
val & = ~ ( SPRD_SPI_START_RX | SPRD_SPI_ONLY_RECV_MASK ) ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL4 ) ;
/* Set the receive data length */
val = readl_relaxed ( ss - > base + SPRD_SPI_CTL4 ) ;
val | = len & SPRD_SPI_ONLY_RECV_MASK ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL4 ) ;
/* Trigger to receive data */
val = readl_relaxed ( ss - > base + SPRD_SPI_CTL4 ) ;
val | = SPRD_SPI_START_RX ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL4 ) ;
return len ;
}
static int sprd_spi_write_bufs_u8 ( struct sprd_spi * ss , u32 len )
{
u8 * tx_p = ( u8 * ) ss - > tx_buf ;
int i ;
for ( i = 0 ; i < len ; i + + )
writeb_relaxed ( tx_p [ i ] , ss - > base + SPRD_SPI_TXD ) ;
ss - > tx_buf + = i ;
return i ;
}
static int sprd_spi_write_bufs_u16 ( struct sprd_spi * ss , u32 len )
{
u16 * tx_p = ( u16 * ) ss - > tx_buf ;
int i ;
for ( i = 0 ; i < len ; i + + )
writew_relaxed ( tx_p [ i ] , ss - > base + SPRD_SPI_TXD ) ;
ss - > tx_buf + = i < < 1 ;
return i < < 1 ;
}
static int sprd_spi_write_bufs_u32 ( struct sprd_spi * ss , u32 len )
{
u32 * tx_p = ( u32 * ) ss - > tx_buf ;
int i ;
for ( i = 0 ; i < len ; i + + )
writel_relaxed ( tx_p [ i ] , ss - > base + SPRD_SPI_TXD ) ;
ss - > tx_buf + = i < < 2 ;
return i < < 2 ;
}
static int sprd_spi_read_bufs_u8 ( struct sprd_spi * ss , u32 len )
{
u8 * rx_p = ( u8 * ) ss - > rx_buf ;
int i ;
for ( i = 0 ; i < len ; i + + )
rx_p [ i ] = readb_relaxed ( ss - > base + SPRD_SPI_TXD ) ;
ss - > rx_buf + = i ;
return i ;
}
static int sprd_spi_read_bufs_u16 ( struct sprd_spi * ss , u32 len )
{
u16 * rx_p = ( u16 * ) ss - > rx_buf ;
int i ;
for ( i = 0 ; i < len ; i + + )
rx_p [ i ] = readw_relaxed ( ss - > base + SPRD_SPI_TXD ) ;
ss - > rx_buf + = i < < 1 ;
return i < < 1 ;
}
static int sprd_spi_read_bufs_u32 ( struct sprd_spi * ss , u32 len )
{
u32 * rx_p = ( u32 * ) ss - > rx_buf ;
int i ;
for ( i = 0 ; i < len ; i + + )
rx_p [ i ] = readl_relaxed ( ss - > base + SPRD_SPI_TXD ) ;
ss - > rx_buf + = i < < 2 ;
return i < < 2 ;
}
static int sprd_spi_txrx_bufs ( struct spi_device * sdev , struct spi_transfer * t )
{
struct sprd_spi * ss = spi_controller_get_devdata ( sdev - > controller ) ;
u32 trans_len = ss - > trans_len , len ;
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int ret , write_size = 0 , read_size = 0 ;
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while ( trans_len ) {
len = trans_len > SPRD_SPI_FIFO_SIZE ? SPRD_SPI_FIFO_SIZE :
trans_len ;
if ( ss - > trans_mode & SPRD_SPI_TX_MODE ) {
sprd_spi_set_tx_length ( ss , len ) ;
write_size + = ss - > write_bufs ( ss , len ) ;
/*
* For our 3 wires mode or dual TX line mode , we need
* to request the controller to transfer .
*/
if ( ss - > hw_mode & SPI_3WIRE | | ss - > hw_mode & SPI_TX_DUAL )
sprd_spi_tx_req ( ss ) ;
ret = sprd_spi_wait_for_tx_end ( ss , t ) ;
} else {
sprd_spi_set_rx_length ( ss , len ) ;
/*
* For our 3 wires mode or dual TX line mode , we need
* to request the controller to read .
*/
if ( ss - > hw_mode & SPI_3WIRE | | ss - > hw_mode & SPI_TX_DUAL )
sprd_spi_rx_req ( ss ) ;
else
write_size + = ss - > write_bufs ( ss , len ) ;
ret = sprd_spi_wait_for_rx_end ( ss , t ) ;
}
if ( ret )
goto complete ;
if ( ss - > trans_mode & SPRD_SPI_RX_MODE )
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read_size + = ss - > read_bufs ( ss , len ) ;
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trans_len - = len ;
}
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if ( ss - > trans_mode & SPRD_SPI_TX_MODE )
ret = write_size ;
else
ret = read_size ;
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complete :
sprd_spi_enter_idle ( ss ) ;
return ret ;
}
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static void sprd_spi_irq_enable ( struct sprd_spi * ss )
{
u32 val ;
/* Clear interrupt status before enabling interrupt. */
writel_relaxed ( SPRD_SPI_TX_END_CLR | SPRD_SPI_RX_END_CLR ,
ss - > base + SPRD_SPI_INT_CLR ) ;
/* Enable SPI interrupt only in DMA mode. */
val = readl_relaxed ( ss - > base + SPRD_SPI_INT_EN ) ;
writel_relaxed ( val | SPRD_SPI_TX_END_INT_EN |
SPRD_SPI_RX_END_INT_EN ,
ss - > base + SPRD_SPI_INT_EN ) ;
}
static void sprd_spi_irq_disable ( struct sprd_spi * ss )
{
writel_relaxed ( 0 , ss - > base + SPRD_SPI_INT_EN ) ;
}
static void sprd_spi_dma_enable ( struct sprd_spi * ss , bool enable )
{
u32 val = readl_relaxed ( ss - > base + SPRD_SPI_CTL2 ) ;
if ( enable )
val | = SPRD_SPI_DMA_EN ;
else
val & = ~ SPRD_SPI_DMA_EN ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL2 ) ;
}
static int sprd_spi_dma_submit ( struct dma_chan * dma_chan ,
struct dma_slave_config * c ,
struct sg_table * sg ,
enum dma_transfer_direction dir )
{
struct dma_async_tx_descriptor * desc ;
dma_cookie_t cookie ;
unsigned long flags ;
int ret ;
ret = dmaengine_slave_config ( dma_chan , c ) ;
if ( ret < 0 )
return ret ;
flags = SPRD_DMA_FLAGS ( SPRD_DMA_CHN_MODE_NONE , SPRD_DMA_NO_TRG ,
SPRD_DMA_FRAG_REQ , SPRD_DMA_TRANS_INT ) ;
desc = dmaengine_prep_slave_sg ( dma_chan , sg - > sgl , sg - > nents , dir , flags ) ;
if ( ! desc )
return - ENODEV ;
cookie = dmaengine_submit ( desc ) ;
if ( dma_submit_error ( cookie ) )
return dma_submit_error ( cookie ) ;
dma_async_issue_pending ( dma_chan ) ;
return 0 ;
}
static int sprd_spi_dma_rx_config ( struct sprd_spi * ss , struct spi_transfer * t )
{
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struct dma_chan * dma_chan = ss - > dma . dma_chan [ SPRD_SPI_RX ] ;
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struct dma_slave_config config = {
. src_addr = ss - > phy_base ,
. src_addr_width = ss - > dma . width ,
. dst_addr_width = ss - > dma . width ,
. dst_maxburst = ss - > dma . fragmens_len ,
} ;
int ret ;
ret = sprd_spi_dma_submit ( dma_chan , & config , & t - > rx_sg , DMA_DEV_TO_MEM ) ;
if ( ret )
return ret ;
return ss - > dma . rx_len ;
}
static int sprd_spi_dma_tx_config ( struct sprd_spi * ss , struct spi_transfer * t )
{
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struct dma_chan * dma_chan = ss - > dma . dma_chan [ SPRD_SPI_TX ] ;
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struct dma_slave_config config = {
. dst_addr = ss - > phy_base ,
. src_addr_width = ss - > dma . width ,
. dst_addr_width = ss - > dma . width ,
. src_maxburst = ss - > dma . fragmens_len ,
} ;
int ret ;
ret = sprd_spi_dma_submit ( dma_chan , & config , & t - > tx_sg , DMA_MEM_TO_DEV ) ;
if ( ret )
return ret ;
return t - > len ;
}
static int sprd_spi_dma_request ( struct sprd_spi * ss )
{
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ss - > dma . dma_chan [ SPRD_SPI_RX ] = dma_request_chan ( ss - > dev , " rx_chn " ) ;
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if ( IS_ERR_OR_NULL ( ss - > dma . dma_chan [ SPRD_SPI_RX ] ) )
return dev_err_probe ( ss - > dev , PTR_ERR ( ss - > dma . dma_chan [ SPRD_SPI_RX ] ) ,
" request RX DMA channel failed! \n " ) ;
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ss - > dma . dma_chan [ SPRD_SPI_TX ] = dma_request_chan ( ss - > dev , " tx_chn " ) ;
if ( IS_ERR_OR_NULL ( ss - > dma . dma_chan [ SPRD_SPI_TX ] ) ) {
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dma_release_channel ( ss - > dma . dma_chan [ SPRD_SPI_RX ] ) ;
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return dev_err_probe ( ss - > dev , PTR_ERR ( ss - > dma . dma_chan [ SPRD_SPI_TX ] ) ,
" request TX DMA channel failed! \n " ) ;
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}
return 0 ;
}
static void sprd_spi_dma_release ( struct sprd_spi * ss )
{
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if ( ss - > dma . dma_chan [ SPRD_SPI_RX ] )
dma_release_channel ( ss - > dma . dma_chan [ SPRD_SPI_RX ] ) ;
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if ( ss - > dma . dma_chan [ SPRD_SPI_TX ] )
dma_release_channel ( ss - > dma . dma_chan [ SPRD_SPI_TX ] ) ;
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}
static int sprd_spi_dma_txrx_bufs ( struct spi_device * sdev ,
struct spi_transfer * t )
{
struct sprd_spi * ss = spi_master_get_devdata ( sdev - > master ) ;
u32 trans_len = ss - > trans_len ;
int ret , write_size = 0 ;
reinit_completion ( & ss - > xfer_completion ) ;
sprd_spi_irq_enable ( ss ) ;
if ( ss - > trans_mode & SPRD_SPI_TX_MODE ) {
write_size = sprd_spi_dma_tx_config ( ss , t ) ;
sprd_spi_set_tx_length ( ss , trans_len ) ;
/*
* For our 3 wires mode or dual TX line mode , we need
* to request the controller to transfer .
*/
if ( ss - > hw_mode & SPI_3WIRE | | ss - > hw_mode & SPI_TX_DUAL )
sprd_spi_tx_req ( ss ) ;
} else {
sprd_spi_set_rx_length ( ss , trans_len ) ;
/*
* For our 3 wires mode or dual TX line mode , we need
* to request the controller to read .
*/
if ( ss - > hw_mode & SPI_3WIRE | | ss - > hw_mode & SPI_TX_DUAL )
sprd_spi_rx_req ( ss ) ;
else
write_size = ss - > write_bufs ( ss , trans_len ) ;
}
if ( write_size < 0 ) {
ret = write_size ;
dev_err ( ss - > dev , " failed to write, ret = %d \n " , ret ) ;
goto trans_complete ;
}
if ( ss - > trans_mode & SPRD_SPI_RX_MODE ) {
/*
* Set up the DMA receive data length , which must be an
* integral multiple of fragment length . But when the length
* of received data is less than fragment length , DMA can be
* configured to receive data according to the actual length
* of received data .
*/
ss - > dma . rx_len = t - > len > ss - > dma . fragmens_len ?
( t - > len - t - > len % ss - > dma . fragmens_len ) :
t - > len ;
ret = sprd_spi_dma_rx_config ( ss , t ) ;
if ( ret < 0 ) {
dev_err ( & sdev - > dev ,
" failed to configure rx DMA, ret = %d \n " , ret ) ;
goto trans_complete ;
}
}
sprd_spi_dma_enable ( ss , true ) ;
wait_for_completion ( & ( ss - > xfer_completion ) ) ;
if ( ss - > trans_mode & SPRD_SPI_TX_MODE )
ret = write_size ;
else
ret = ss - > dma . rx_len ;
trans_complete :
sprd_spi_dma_enable ( ss , false ) ;
sprd_spi_enter_idle ( ss ) ;
sprd_spi_irq_disable ( ss ) ;
return ret ;
}
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static void sprd_spi_set_speed ( struct sprd_spi * ss , u32 speed_hz )
{
/*
* From SPI datasheet , the prescale calculation formula :
* prescale = SPI source clock / ( 2 * SPI_freq ) - 1 ;
*/
u32 clk_div = DIV_ROUND_UP ( ss - > src_clk , speed_hz < < 1 ) - 1 ;
/* Save the real hardware speed */
ss - > hw_speed_hz = ( ss - > src_clk > > 1 ) / ( clk_div + 1 ) ;
writel_relaxed ( clk_div , ss - > base + SPRD_SPI_CLKD ) ;
}
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static int sprd_spi_init_hw ( struct sprd_spi * ss , struct spi_transfer * t )
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{
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struct spi_delay * d = & t - > word_delay ;
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u16 word_delay , interval ;
u32 val ;
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if ( d - > unit ! = SPI_DELAY_UNIT_SCK )
return - EINVAL ;
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val = readl_relaxed ( ss - > base + SPRD_SPI_CTL0 ) ;
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val & = ~ ( SPRD_SPI_SCK_REV | SPRD_SPI_NG_TX | SPRD_SPI_NG_RX ) ;
/* Set default chip selection, clock phase and clock polarity */
val | = ss - > hw_mode & SPI_CPHA ? SPRD_SPI_NG_RX : SPRD_SPI_NG_TX ;
val | = ss - > hw_mode & SPI_CPOL ? SPRD_SPI_SCK_REV : 0 ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL0 ) ;
/*
* Set the intervals of two SPI frames , and the inteval calculation
* formula as below per datasheet :
* interval time ( source clock cycles ) = interval * 4 + 10.
*/
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word_delay = clamp_t ( u16 , d - > value , SPRD_SPI_MIN_DELAY_CYCLE ,
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SPRD_SPI_MAX_DELAY_CYCLE ) ;
interval = DIV_ROUND_UP ( word_delay - 10 , 4 ) ;
ss - > word_delay = interval * 4 + 10 ;
writel_relaxed ( interval , ss - > base + SPRD_SPI_CTL5 ) ;
/* Reset SPI fifo */
writel_relaxed ( 1 , ss - > base + SPRD_SPI_FIFO_RST ) ;
writel_relaxed ( 0 , ss - > base + SPRD_SPI_FIFO_RST ) ;
/* Set SPI work mode */
val = readl_relaxed ( ss - > base + SPRD_SPI_CTL7 ) ;
val & = ~ SPRD_SPI_MODE_MASK ;
if ( ss - > hw_mode & SPI_3WIRE )
val | = SPRD_SPI_3WIRE_MODE < < SPRD_SPI_MODE_OFFSET ;
else
val | = SPRD_SPI_4WIRE_MODE < < SPRD_SPI_MODE_OFFSET ;
if ( ss - > hw_mode & SPI_TX_DUAL )
val | = SPRD_SPI_DATA_LINE2_EN ;
else
val & = ~ SPRD_SPI_DATA_LINE2_EN ;
writel_relaxed ( val , ss - > base + SPRD_SPI_CTL7 ) ;
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return 0 ;
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}
static int sprd_spi_setup_transfer ( struct spi_device * sdev ,
struct spi_transfer * t )
{
struct sprd_spi * ss = spi_controller_get_devdata ( sdev - > controller ) ;
u8 bits_per_word = t - > bits_per_word ;
u32 val , mode = 0 ;
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int ret ;
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ss - > len = t - > len ;
ss - > tx_buf = t - > tx_buf ;
ss - > rx_buf = t - > rx_buf ;
ss - > hw_mode = sdev - > mode ;
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ret = sprd_spi_init_hw ( ss , t ) ;
if ( ret )
return ret ;
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/* Set tansfer speed and valid bits */
sprd_spi_set_speed ( ss , t - > speed_hz ) ;
sprd_spi_set_transfer_bits ( ss , bits_per_word ) ;
if ( bits_per_word > 16 )
bits_per_word = round_up ( bits_per_word , 16 ) ;
else
bits_per_word = round_up ( bits_per_word , 8 ) ;
switch ( bits_per_word ) {
case 8 :
ss - > trans_len = t - > len ;
ss - > read_bufs = sprd_spi_read_bufs_u8 ;
ss - > write_bufs = sprd_spi_write_bufs_u8 ;
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ss - > dma . width = DMA_SLAVE_BUSWIDTH_1_BYTE ;
ss - > dma . fragmens_len = SPRD_SPI_DMA_STEP ;
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break ;
case 16 :
ss - > trans_len = t - > len > > 1 ;
ss - > read_bufs = sprd_spi_read_bufs_u16 ;
ss - > write_bufs = sprd_spi_write_bufs_u16 ;
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ss - > dma . width = DMA_SLAVE_BUSWIDTH_2_BYTES ;
ss - > dma . fragmens_len = SPRD_SPI_DMA_STEP < < 1 ;
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break ;
case 32 :
ss - > trans_len = t - > len > > 2 ;
ss - > read_bufs = sprd_spi_read_bufs_u32 ;
ss - > write_bufs = sprd_spi_write_bufs_u32 ;
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ss - > dma . width = DMA_SLAVE_BUSWIDTH_4_BYTES ;
ss - > dma . fragmens_len = SPRD_SPI_DMA_STEP < < 2 ;
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break ;
default :
return - EINVAL ;
}
/* Set transfer read or write mode */
val = readl_relaxed ( ss - > base + SPRD_SPI_CTL1 ) ;
val & = ~ SPRD_SPI_RTX_MD_MASK ;
if ( t - > tx_buf )
mode | = SPRD_SPI_TX_MODE ;
if ( t - > rx_buf )
mode | = SPRD_SPI_RX_MODE ;
writel_relaxed ( val | mode , ss - > base + SPRD_SPI_CTL1 ) ;
ss - > trans_mode = mode ;
/*
* If in only receive mode , we need to trigger the SPI controller to
* receive data automatically .
*/
if ( ss - > trans_mode = = SPRD_SPI_RX_MODE )
ss - > write_bufs = sprd_spi_write_only_receive ;
return 0 ;
}
static int sprd_spi_transfer_one ( struct spi_controller * sctlr ,
struct spi_device * sdev ,
struct spi_transfer * t )
{
int ret ;
ret = sprd_spi_setup_transfer ( sdev , t ) ;
if ( ret )
goto setup_err ;
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if ( sctlr - > can_dma ( sctlr , sdev , t ) )
ret = sprd_spi_dma_txrx_bufs ( sdev , t ) ;
else
ret = sprd_spi_txrx_bufs ( sdev , t ) ;
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if ( ret = = t - > len )
ret = 0 ;
else if ( ret > = 0 )
ret = - EREMOTEIO ;
setup_err :
spi_finalize_current_transfer ( sctlr ) ;
return ret ;
}
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static irqreturn_t sprd_spi_handle_irq ( int irq , void * data )
{
struct sprd_spi * ss = ( struct sprd_spi * ) data ;
u32 val = readl_relaxed ( ss - > base + SPRD_SPI_INT_MASK_STS ) ;
if ( val & SPRD_SPI_MASK_TX_END ) {
writel_relaxed ( SPRD_SPI_TX_END_CLR , ss - > base + SPRD_SPI_INT_CLR ) ;
if ( ! ( ss - > trans_mode & SPRD_SPI_RX_MODE ) )
complete ( & ss - > xfer_completion ) ;
return IRQ_HANDLED ;
}
if ( val & SPRD_SPI_MASK_RX_END ) {
writel_relaxed ( SPRD_SPI_RX_END_CLR , ss - > base + SPRD_SPI_INT_CLR ) ;
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if ( ss - > dma . rx_len < ss - > len ) {
ss - > rx_buf + = ss - > dma . rx_len ;
ss - > dma . rx_len + =
ss - > read_bufs ( ss , ss - > len - ss - > dma . rx_len ) ;
}
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complete ( & ss - > xfer_completion ) ;
return IRQ_HANDLED ;
}
return IRQ_NONE ;
}
static int sprd_spi_irq_init ( struct platform_device * pdev , struct sprd_spi * ss )
{
int ret ;
ss - > irq = platform_get_irq ( pdev , 0 ) ;
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if ( ss - > irq < 0 )
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return ss - > irq ;
ret = devm_request_irq ( & pdev - > dev , ss - > irq , sprd_spi_handle_irq ,
0 , pdev - > name , ss ) ;
if ( ret )
dev_err ( & pdev - > dev , " failed to request spi irq %d, ret = %d \n " ,
ss - > irq , ret ) ;
return ret ;
}
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static int sprd_spi_clk_init ( struct platform_device * pdev , struct sprd_spi * ss )
{
struct clk * clk_spi , * clk_parent ;
clk_spi = devm_clk_get ( & pdev - > dev , " spi " ) ;
if ( IS_ERR ( clk_spi ) ) {
dev_warn ( & pdev - > dev , " can't get the spi clock \n " ) ;
clk_spi = NULL ;
}
clk_parent = devm_clk_get ( & pdev - > dev , " source " ) ;
if ( IS_ERR ( clk_parent ) ) {
dev_warn ( & pdev - > dev , " can't get the source clock \n " ) ;
clk_parent = NULL ;
}
ss - > clk = devm_clk_get ( & pdev - > dev , " enable " ) ;
if ( IS_ERR ( ss - > clk ) ) {
dev_err ( & pdev - > dev , " can't get the enable clock \n " ) ;
return PTR_ERR ( ss - > clk ) ;
}
if ( ! clk_set_parent ( clk_spi , clk_parent ) )
ss - > src_clk = clk_get_rate ( clk_spi ) ;
else
ss - > src_clk = SPRD_SPI_DEFAULT_SOURCE ;
return 0 ;
}
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static bool sprd_spi_can_dma ( struct spi_controller * sctlr ,
struct spi_device * spi , struct spi_transfer * t )
{
struct sprd_spi * ss = spi_controller_get_devdata ( sctlr ) ;
return ss - > dma . enable & & ( t - > len > SPRD_SPI_FIFO_SIZE ) ;
}
static int sprd_spi_dma_init ( struct platform_device * pdev , struct sprd_spi * ss )
{
int ret ;
ret = sprd_spi_dma_request ( ss ) ;
if ( ret ) {
if ( ret = = - EPROBE_DEFER )
return ret ;
dev_warn ( & pdev - > dev ,
" failed to request dma, enter no dma mode, ret = %d \n " ,
ret ) ;
return 0 ;
}
ss - > dma . enable = true ;
return 0 ;
}
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static int sprd_spi_probe ( struct platform_device * pdev )
{
struct spi_controller * sctlr ;
struct resource * res ;
struct sprd_spi * ss ;
int ret ;
pdev - > id = of_alias_get_id ( pdev - > dev . of_node , " spi " ) ;
sctlr = spi_alloc_master ( & pdev - > dev , sizeof ( * ss ) ) ;
if ( ! sctlr )
return - ENOMEM ;
ss = spi_controller_get_devdata ( sctlr ) ;
res = platform_get_resource ( pdev , IORESOURCE_MEM , 0 ) ;
ss - > base = devm_ioremap_resource ( & pdev - > dev , res ) ;
if ( IS_ERR ( ss - > base ) ) {
ret = PTR_ERR ( ss - > base ) ;
goto free_controller ;
}
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ss - > phy_base = res - > start ;
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ss - > dev = & pdev - > dev ;
sctlr - > dev . of_node = pdev - > dev . of_node ;
sctlr - > mode_bits = SPI_CPOL | SPI_CPHA | SPI_3WIRE | SPI_TX_DUAL ;
sctlr - > bus_num = pdev - > id ;
sctlr - > set_cs = sprd_spi_chipselect ;
sctlr - > transfer_one = sprd_spi_transfer_one ;
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sctlr - > can_dma = sprd_spi_can_dma ;
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sctlr - > auto_runtime_pm = true ;
sctlr - > max_speed_hz = min_t ( u32 , ss - > src_clk > > 1 ,
SPRD_SPI_MAX_SPEED_HZ ) ;
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init_completion ( & ss - > xfer_completion ) ;
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platform_set_drvdata ( pdev , sctlr ) ;
ret = sprd_spi_clk_init ( pdev , ss ) ;
if ( ret )
goto free_controller ;
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ret = sprd_spi_irq_init ( pdev , ss ) ;
if ( ret )
goto free_controller ;
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ret = sprd_spi_dma_init ( pdev , ss ) ;
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if ( ret )
goto free_controller ;
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ret = clk_prepare_enable ( ss - > clk ) ;
if ( ret )
goto release_dma ;
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ret = pm_runtime_set_active ( & pdev - > dev ) ;
if ( ret < 0 )
goto disable_clk ;
pm_runtime_set_autosuspend_delay ( & pdev - > dev ,
SPRD_SPI_AUTOSUSPEND_DELAY ) ;
pm_runtime_use_autosuspend ( & pdev - > dev ) ;
pm_runtime_enable ( & pdev - > dev ) ;
ret = pm_runtime_get_sync ( & pdev - > dev ) ;
if ( ret < 0 ) {
dev_err ( & pdev - > dev , " failed to resume SPI controller \n " ) ;
goto err_rpm_put ;
}
ret = devm_spi_register_controller ( & pdev - > dev , sctlr ) ;
if ( ret )
goto err_rpm_put ;
pm_runtime_mark_last_busy ( & pdev - > dev ) ;
pm_runtime_put_autosuspend ( & pdev - > dev ) ;
return 0 ;
err_rpm_put :
pm_runtime_put_noidle ( & pdev - > dev ) ;
pm_runtime_disable ( & pdev - > dev ) ;
disable_clk :
clk_disable_unprepare ( ss - > clk ) ;
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release_dma :
sprd_spi_dma_release ( ss ) ;
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free_controller :
spi_controller_put ( sctlr ) ;
return ret ;
}
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static int sprd_spi_remove ( struct platform_device * pdev )
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{
struct spi_controller * sctlr = platform_get_drvdata ( pdev ) ;
struct sprd_spi * ss = spi_controller_get_devdata ( sctlr ) ;
int ret ;
ret = pm_runtime_get_sync ( ss - > dev ) ;
if ( ret < 0 ) {
2020-11-06 04:50:35 +03:00
pm_runtime_put_noidle ( ss - > dev ) ;
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dev_err ( ss - > dev , " failed to resume SPI controller \n " ) ;
return ret ;
}
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spi_controller_suspend ( sctlr ) ;
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if ( ss - > dma . enable )
sprd_spi_dma_release ( ss ) ;
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clk_disable_unprepare ( ss - > clk ) ;
pm_runtime_put_noidle ( & pdev - > dev ) ;
pm_runtime_disable ( & pdev - > dev ) ;
return 0 ;
}
static int __maybe_unused sprd_spi_runtime_suspend ( struct device * dev )
{
struct spi_controller * sctlr = dev_get_drvdata ( dev ) ;
struct sprd_spi * ss = spi_controller_get_devdata ( sctlr ) ;
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if ( ss - > dma . enable )
sprd_spi_dma_release ( ss ) ;
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clk_disable_unprepare ( ss - > clk ) ;
return 0 ;
}
static int __maybe_unused sprd_spi_runtime_resume ( struct device * dev )
{
struct spi_controller * sctlr = dev_get_drvdata ( dev ) ;
struct sprd_spi * ss = spi_controller_get_devdata ( sctlr ) ;
int ret ;
ret = clk_prepare_enable ( ss - > clk ) ;
if ( ret )
return ret ;
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if ( ! ss - > dma . enable )
return 0 ;
ret = sprd_spi_dma_request ( ss ) ;
if ( ret )
clk_disable_unprepare ( ss - > clk ) ;
return ret ;
2018-08-16 15:54:51 +03:00
}
static const struct dev_pm_ops sprd_spi_pm_ops = {
SET_RUNTIME_PM_OPS ( sprd_spi_runtime_suspend ,
sprd_spi_runtime_resume , NULL )
} ;
static const struct of_device_id sprd_spi_of_match [ ] = {
{ . compatible = " sprd,sc9860-spi " , } ,
{ /* sentinel */ }
} ;
static struct platform_driver sprd_spi_driver = {
. driver = {
. name = " sprd-spi " ,
. of_match_table = sprd_spi_of_match ,
. pm = & sprd_spi_pm_ops ,
} ,
. probe = sprd_spi_probe ,
. remove = sprd_spi_remove ,
} ;
module_platform_driver ( sprd_spi_driver ) ;
MODULE_DESCRIPTION ( " Spreadtrum SPI Controller driver " ) ;
MODULE_AUTHOR ( " Lanqing Liu <lanqing.liu@spreadtrum.com> " ) ;
MODULE_LICENSE ( " GPL v2 " ) ;