linux/drivers/spi/spi-axi-spi-engine.c

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// SPDX-License-Identifier: GPL-2.0-only
spi: Add Analog Devices AXI SPI Engine controller support This patch adds support for the AXI SPI Engine controller which is a FPGA soft-peripheral which is used in some of Analog Devices' reference designs. The AXI SPI Engine controller is part of the SPI Engine framework[1] and allows memory mapped access to the SPI Engine control bus. This allows it to be used as a general purpose software driven SPI controller. The SPI Engine in addition offers some optional advanced acceleration and offloading capabilities, which are not part of this patch though and will be introduced separately. At the core of the SPI Engine framework is a small sort of co-processor that accepts a command stream and turns the commands into low-level SPI transactions. Communication is done through three memory mapped FIFOs in the register map of the AXI SPI Engine peripheral. One FIFO for the command stream and one each for transmit and receive data. The driver translates a spi_message in a command stream and writes it to the peripheral which executes it asynchronously. This allows it to perform very precise timings which are required for some SPI slave devices to achieve maximum performance (e.g. analog-to-digital and digital-to-analog converters). The execution flow is synchronized to the host system by a special synchronize instruction which generates a interrupt. [1] https://wiki.analog.com/resources/fpga/peripherals/spi_engine Signed-off-by: Lars-Peter Clausen <lars@metafoo.de> Signed-off-by: Mark Brown <broonie@kernel.org>
2016-02-04 17:13:30 +01:00
/*
* SPI-Engine SPI controller driver
* Copyright 2015 Analog Devices Inc.
* Author: Lars-Peter Clausen <lars@metafoo.de>
*/
#include <linux/clk.h>
#include <linux/interrupt.h>
#include <linux/io.h>
#include <linux/of.h>
#include <linux/module.h>
#include <linux/platform_device.h>
#include <linux/spi/spi.h>
#define SPI_ENGINE_VERSION_MAJOR(x) ((x >> 16) & 0xff)
#define SPI_ENGINE_VERSION_MINOR(x) ((x >> 8) & 0xff)
#define SPI_ENGINE_VERSION_PATCH(x) (x & 0xff)
#define SPI_ENGINE_REG_VERSION 0x00
#define SPI_ENGINE_REG_RESET 0x40
#define SPI_ENGINE_REG_INT_ENABLE 0x80
#define SPI_ENGINE_REG_INT_PENDING 0x84
#define SPI_ENGINE_REG_INT_SOURCE 0x88
#define SPI_ENGINE_REG_SYNC_ID 0xc0
#define SPI_ENGINE_REG_CMD_FIFO_ROOM 0xd0
#define SPI_ENGINE_REG_SDO_FIFO_ROOM 0xd4
#define SPI_ENGINE_REG_SDI_FIFO_LEVEL 0xd8
#define SPI_ENGINE_REG_CMD_FIFO 0xe0
#define SPI_ENGINE_REG_SDO_DATA_FIFO 0xe4
#define SPI_ENGINE_REG_SDI_DATA_FIFO 0xe8
#define SPI_ENGINE_REG_SDI_DATA_FIFO_PEEK 0xec
#define SPI_ENGINE_INT_CMD_ALMOST_EMPTY BIT(0)
#define SPI_ENGINE_INT_SDO_ALMOST_EMPTY BIT(1)
#define SPI_ENGINE_INT_SDI_ALMOST_FULL BIT(2)
#define SPI_ENGINE_INT_SYNC BIT(3)
#define SPI_ENGINE_CONFIG_CPHA BIT(0)
#define SPI_ENGINE_CONFIG_CPOL BIT(1)
#define SPI_ENGINE_CONFIG_3WIRE BIT(2)
#define SPI_ENGINE_INST_TRANSFER 0x0
#define SPI_ENGINE_INST_ASSERT 0x1
#define SPI_ENGINE_INST_WRITE 0x2
#define SPI_ENGINE_INST_MISC 0x3
#define SPI_ENGINE_CMD_REG_CLK_DIV 0x0
#define SPI_ENGINE_CMD_REG_CONFIG 0x1
#define SPI_ENGINE_MISC_SYNC 0x0
#define SPI_ENGINE_MISC_SLEEP 0x1
#define SPI_ENGINE_TRANSFER_WRITE 0x1
#define SPI_ENGINE_TRANSFER_READ 0x2
#define SPI_ENGINE_CMD(inst, arg1, arg2) \
(((inst) << 12) | ((arg1) << 8) | (arg2))
#define SPI_ENGINE_CMD_TRANSFER(flags, n) \
SPI_ENGINE_CMD(SPI_ENGINE_INST_TRANSFER, (flags), (n))
#define SPI_ENGINE_CMD_ASSERT(delay, cs) \
SPI_ENGINE_CMD(SPI_ENGINE_INST_ASSERT, (delay), (cs))
#define SPI_ENGINE_CMD_WRITE(reg, val) \
SPI_ENGINE_CMD(SPI_ENGINE_INST_WRITE, (reg), (val))
#define SPI_ENGINE_CMD_SLEEP(delay) \
SPI_ENGINE_CMD(SPI_ENGINE_INST_MISC, SPI_ENGINE_MISC_SLEEP, (delay))
#define SPI_ENGINE_CMD_SYNC(id) \
SPI_ENGINE_CMD(SPI_ENGINE_INST_MISC, SPI_ENGINE_MISC_SYNC, (id))
struct spi_engine_program {
unsigned int length;
uint16_t instructions[];
};
struct spi_engine {
struct clk *clk;
struct clk *ref_clk;
spinlock_t lock;
void __iomem *base;
struct spi_message *msg;
struct spi_engine_program *p;
unsigned cmd_length;
const uint16_t *cmd_buf;
struct spi_transfer *tx_xfer;
unsigned int tx_length;
const uint8_t *tx_buf;
struct spi_transfer *rx_xfer;
unsigned int rx_length;
uint8_t *rx_buf;
unsigned int sync_id;
unsigned int completed_id;
unsigned int int_enable;
};
static void spi_engine_program_add_cmd(struct spi_engine_program *p,
bool dry, uint16_t cmd)
{
if (!dry)
p->instructions[p->length] = cmd;
p->length++;
}
static unsigned int spi_engine_get_config(struct spi_device *spi)
{
unsigned int config = 0;
if (spi->mode & SPI_CPOL)
config |= SPI_ENGINE_CONFIG_CPOL;
if (spi->mode & SPI_CPHA)
config |= SPI_ENGINE_CONFIG_CPHA;
if (spi->mode & SPI_3WIRE)
config |= SPI_ENGINE_CONFIG_3WIRE;
return config;
}
static unsigned int spi_engine_get_clk_div(struct spi_engine *spi_engine,
struct spi_device *spi, struct spi_transfer *xfer)
{
unsigned int clk_div;
clk_div = DIV_ROUND_UP(clk_get_rate(spi_engine->ref_clk),
xfer->speed_hz * 2);
if (clk_div > 255)
clk_div = 255;
else if (clk_div > 0)
clk_div -= 1;
return clk_div;
}
static void spi_engine_gen_xfer(struct spi_engine_program *p, bool dry,
struct spi_transfer *xfer)
{
unsigned int len = xfer->len;
while (len) {
unsigned int n = min(len, 256U);
unsigned int flags = 0;
if (xfer->tx_buf)
flags |= SPI_ENGINE_TRANSFER_WRITE;
if (xfer->rx_buf)
flags |= SPI_ENGINE_TRANSFER_READ;
spi_engine_program_add_cmd(p, dry,
SPI_ENGINE_CMD_TRANSFER(flags, n - 1));
len -= n;
}
}
static void spi_engine_gen_sleep(struct spi_engine_program *p, bool dry,
struct spi_engine *spi_engine, unsigned int clk_div, unsigned int delay)
{
unsigned int spi_clk = clk_get_rate(spi_engine->ref_clk);
unsigned int t;
if (delay == 0)
return;
t = DIV_ROUND_UP(delay * spi_clk, (clk_div + 1) * 2);
while (t) {
unsigned int n = min(t, 256U);
spi_engine_program_add_cmd(p, dry, SPI_ENGINE_CMD_SLEEP(n - 1));
t -= n;
}
}
static void spi_engine_gen_cs(struct spi_engine_program *p, bool dry,
struct spi_device *spi, bool assert)
{
unsigned int mask = 0xff;
if (assert)
mask ^= BIT(spi->chip_select);
spi_engine_program_add_cmd(p, dry, SPI_ENGINE_CMD_ASSERT(1, mask));
}
static int spi_engine_compile_message(struct spi_engine *spi_engine,
struct spi_message *msg, bool dry, struct spi_engine_program *p)
{
struct spi_device *spi = msg->spi;
struct spi_transfer *xfer;
int clk_div, new_clk_div;
bool cs_change = true;
clk_div = -1;
spi_engine_program_add_cmd(p, dry,
SPI_ENGINE_CMD_WRITE(SPI_ENGINE_CMD_REG_CONFIG,
spi_engine_get_config(spi)));
list_for_each_entry(xfer, &msg->transfers, transfer_list) {
new_clk_div = spi_engine_get_clk_div(spi_engine, spi, xfer);
if (new_clk_div != clk_div) {
clk_div = new_clk_div;
spi_engine_program_add_cmd(p, dry,
SPI_ENGINE_CMD_WRITE(SPI_ENGINE_CMD_REG_CLK_DIV,
clk_div));
}
if (cs_change)
spi_engine_gen_cs(p, dry, spi, true);
spi_engine_gen_xfer(p, dry, xfer);
spi_engine_gen_sleep(p, dry, spi_engine, clk_div,
xfer->delay_usecs);
cs_change = xfer->cs_change;
if (list_is_last(&xfer->transfer_list, &msg->transfers))
cs_change = !cs_change;
if (cs_change)
spi_engine_gen_cs(p, dry, spi, false);
}
return 0;
}
static void spi_engine_xfer_next(struct spi_engine *spi_engine,
struct spi_transfer **_xfer)
{
struct spi_message *msg = spi_engine->msg;
struct spi_transfer *xfer = *_xfer;
if (!xfer) {
xfer = list_first_entry(&msg->transfers,
struct spi_transfer, transfer_list);
} else if (list_is_last(&xfer->transfer_list, &msg->transfers)) {
xfer = NULL;
} else {
xfer = list_next_entry(xfer, transfer_list);
}
*_xfer = xfer;
}
static void spi_engine_tx_next(struct spi_engine *spi_engine)
{
struct spi_transfer *xfer = spi_engine->tx_xfer;
do {
spi_engine_xfer_next(spi_engine, &xfer);
} while (xfer && !xfer->tx_buf);
spi_engine->tx_xfer = xfer;
if (xfer) {
spi_engine->tx_length = xfer->len;
spi_engine->tx_buf = xfer->tx_buf;
} else {
spi_engine->tx_buf = NULL;
}
}
static void spi_engine_rx_next(struct spi_engine *spi_engine)
{
struct spi_transfer *xfer = spi_engine->rx_xfer;
do {
spi_engine_xfer_next(spi_engine, &xfer);
} while (xfer && !xfer->rx_buf);
spi_engine->rx_xfer = xfer;
if (xfer) {
spi_engine->rx_length = xfer->len;
spi_engine->rx_buf = xfer->rx_buf;
} else {
spi_engine->rx_buf = NULL;
}
}
static bool spi_engine_write_cmd_fifo(struct spi_engine *spi_engine)
{
void __iomem *addr = spi_engine->base + SPI_ENGINE_REG_CMD_FIFO;
unsigned int n, m, i;
const uint16_t *buf;
n = readl_relaxed(spi_engine->base + SPI_ENGINE_REG_CMD_FIFO_ROOM);
while (n && spi_engine->cmd_length) {
m = min(n, spi_engine->cmd_length);
buf = spi_engine->cmd_buf;
for (i = 0; i < m; i++)
writel_relaxed(buf[i], addr);
spi_engine->cmd_buf += m;
spi_engine->cmd_length -= m;
n -= m;
}
return spi_engine->cmd_length != 0;
}
static bool spi_engine_write_tx_fifo(struct spi_engine *spi_engine)
{
void __iomem *addr = spi_engine->base + SPI_ENGINE_REG_SDO_DATA_FIFO;
unsigned int n, m, i;
const uint8_t *buf;
n = readl_relaxed(spi_engine->base + SPI_ENGINE_REG_SDO_FIFO_ROOM);
while (n && spi_engine->tx_length) {
m = min(n, spi_engine->tx_length);
buf = spi_engine->tx_buf;
for (i = 0; i < m; i++)
writel_relaxed(buf[i], addr);
spi_engine->tx_buf += m;
spi_engine->tx_length -= m;
n -= m;
if (spi_engine->tx_length == 0)
spi_engine_tx_next(spi_engine);
}
return spi_engine->tx_length != 0;
}
static bool spi_engine_read_rx_fifo(struct spi_engine *spi_engine)
{
void __iomem *addr = spi_engine->base + SPI_ENGINE_REG_SDI_DATA_FIFO;
unsigned int n, m, i;
uint8_t *buf;
n = readl_relaxed(spi_engine->base + SPI_ENGINE_REG_SDI_FIFO_LEVEL);
while (n && spi_engine->rx_length) {
m = min(n, spi_engine->rx_length);
buf = spi_engine->rx_buf;
for (i = 0; i < m; i++)
buf[i] = readl_relaxed(addr);
spi_engine->rx_buf += m;
spi_engine->rx_length -= m;
n -= m;
if (spi_engine->rx_length == 0)
spi_engine_rx_next(spi_engine);
}
return spi_engine->rx_length != 0;
}
static irqreturn_t spi_engine_irq(int irq, void *devid)
{
struct spi_master *master = devid;
struct spi_engine *spi_engine = spi_master_get_devdata(master);
unsigned int disable_int = 0;
unsigned int pending;
pending = readl_relaxed(spi_engine->base + SPI_ENGINE_REG_INT_PENDING);
if (pending & SPI_ENGINE_INT_SYNC) {
writel_relaxed(SPI_ENGINE_INT_SYNC,
spi_engine->base + SPI_ENGINE_REG_INT_PENDING);
spi_engine->completed_id = readl_relaxed(
spi_engine->base + SPI_ENGINE_REG_SYNC_ID);
}
spin_lock(&spi_engine->lock);
if (pending & SPI_ENGINE_INT_CMD_ALMOST_EMPTY) {
if (!spi_engine_write_cmd_fifo(spi_engine))
disable_int |= SPI_ENGINE_INT_CMD_ALMOST_EMPTY;
}
if (pending & SPI_ENGINE_INT_SDO_ALMOST_EMPTY) {
if (!spi_engine_write_tx_fifo(spi_engine))
disable_int |= SPI_ENGINE_INT_SDO_ALMOST_EMPTY;
}
if (pending & (SPI_ENGINE_INT_SDI_ALMOST_FULL | SPI_ENGINE_INT_SYNC)) {
if (!spi_engine_read_rx_fifo(spi_engine))
disable_int |= SPI_ENGINE_INT_SDI_ALMOST_FULL;
}
if (pending & SPI_ENGINE_INT_SYNC) {
if (spi_engine->msg &&
spi_engine->completed_id == spi_engine->sync_id) {
struct spi_message *msg = spi_engine->msg;
kfree(spi_engine->p);
msg->status = 0;
msg->actual_length = msg->frame_length;
spi_engine->msg = NULL;
spi_finalize_current_message(master);
disable_int |= SPI_ENGINE_INT_SYNC;
}
}
if (disable_int) {
spi_engine->int_enable &= ~disable_int;
writel_relaxed(spi_engine->int_enable,
spi_engine->base + SPI_ENGINE_REG_INT_ENABLE);
}
spin_unlock(&spi_engine->lock);
return IRQ_HANDLED;
}
static int spi_engine_transfer_one_message(struct spi_master *master,
struct spi_message *msg)
{
struct spi_engine_program p_dry, *p;
struct spi_engine *spi_engine = spi_master_get_devdata(master);
unsigned int int_enable = 0;
unsigned long flags;
size_t size;
p_dry.length = 0;
spi_engine_compile_message(spi_engine, msg, true, &p_dry);
size = sizeof(*p->instructions) * (p_dry.length + 1);
p = kzalloc(sizeof(*p) + size, GFP_KERNEL);
if (!p)
return -ENOMEM;
spi_engine_compile_message(spi_engine, msg, false, p);
spin_lock_irqsave(&spi_engine->lock, flags);
spi_engine->sync_id = (spi_engine->sync_id + 1) & 0xff;
spi_engine_program_add_cmd(p, false,
SPI_ENGINE_CMD_SYNC(spi_engine->sync_id));
spi_engine->msg = msg;
spi_engine->p = p;
spi_engine->cmd_buf = p->instructions;
spi_engine->cmd_length = p->length;
if (spi_engine_write_cmd_fifo(spi_engine))
int_enable |= SPI_ENGINE_INT_CMD_ALMOST_EMPTY;
spi_engine_tx_next(spi_engine);
if (spi_engine_write_tx_fifo(spi_engine))
int_enable |= SPI_ENGINE_INT_SDO_ALMOST_EMPTY;
spi_engine_rx_next(spi_engine);
if (spi_engine->rx_length != 0)
int_enable |= SPI_ENGINE_INT_SDI_ALMOST_FULL;
int_enable |= SPI_ENGINE_INT_SYNC;
writel_relaxed(int_enable,
spi_engine->base + SPI_ENGINE_REG_INT_ENABLE);
spi_engine->int_enable = int_enable;
spin_unlock_irqrestore(&spi_engine->lock, flags);
return 0;
}
static int spi_engine_probe(struct platform_device *pdev)
{
struct spi_engine *spi_engine;
struct spi_master *master;
unsigned int version;
int irq;
int ret;
irq = platform_get_irq(pdev, 0);
if (irq <= 0)
return -ENXIO;
spi_engine = devm_kzalloc(&pdev->dev, sizeof(*spi_engine), GFP_KERNEL);
if (!spi_engine)
return -ENOMEM;
master = spi_alloc_master(&pdev->dev, 0);
if (!master)
return -ENOMEM;
spi_master_set_devdata(master, spi_engine);
spin_lock_init(&spi_engine->lock);
spi_engine->base = devm_platform_ioremap_resource(pdev, 0);
spi: Add Analog Devices AXI SPI Engine controller support This patch adds support for the AXI SPI Engine controller which is a FPGA soft-peripheral which is used in some of Analog Devices' reference designs. The AXI SPI Engine controller is part of the SPI Engine framework[1] and allows memory mapped access to the SPI Engine control bus. This allows it to be used as a general purpose software driven SPI controller. The SPI Engine in addition offers some optional advanced acceleration and offloading capabilities, which are not part of this patch though and will be introduced separately. At the core of the SPI Engine framework is a small sort of co-processor that accepts a command stream and turns the commands into low-level SPI transactions. Communication is done through three memory mapped FIFOs in the register map of the AXI SPI Engine peripheral. One FIFO for the command stream and one each for transmit and receive data. The driver translates a spi_message in a command stream and writes it to the peripheral which executes it asynchronously. This allows it to perform very precise timings which are required for some SPI slave devices to achieve maximum performance (e.g. analog-to-digital and digital-to-analog converters). The execution flow is synchronized to the host system by a special synchronize instruction which generates a interrupt. [1] https://wiki.analog.com/resources/fpga/peripherals/spi_engine Signed-off-by: Lars-Peter Clausen <lars@metafoo.de> Signed-off-by: Mark Brown <broonie@kernel.org>
2016-02-04 17:13:30 +01:00
if (IS_ERR(spi_engine->base)) {
ret = PTR_ERR(spi_engine->base);
goto err_put_master;
}
version = readl(spi_engine->base + SPI_ENGINE_REG_VERSION);
if (SPI_ENGINE_VERSION_MAJOR(version) != 1) {
dev_err(&pdev->dev, "Unsupported peripheral version %u.%u.%c\n",
SPI_ENGINE_VERSION_MAJOR(version),
SPI_ENGINE_VERSION_MINOR(version),
SPI_ENGINE_VERSION_PATCH(version));
ret = -ENODEV;
goto err_put_master;
spi: Add Analog Devices AXI SPI Engine controller support This patch adds support for the AXI SPI Engine controller which is a FPGA soft-peripheral which is used in some of Analog Devices' reference designs. The AXI SPI Engine controller is part of the SPI Engine framework[1] and allows memory mapped access to the SPI Engine control bus. This allows it to be used as a general purpose software driven SPI controller. The SPI Engine in addition offers some optional advanced acceleration and offloading capabilities, which are not part of this patch though and will be introduced separately. At the core of the SPI Engine framework is a small sort of co-processor that accepts a command stream and turns the commands into low-level SPI transactions. Communication is done through three memory mapped FIFOs in the register map of the AXI SPI Engine peripheral. One FIFO for the command stream and one each for transmit and receive data. The driver translates a spi_message in a command stream and writes it to the peripheral which executes it asynchronously. This allows it to perform very precise timings which are required for some SPI slave devices to achieve maximum performance (e.g. analog-to-digital and digital-to-analog converters). The execution flow is synchronized to the host system by a special synchronize instruction which generates a interrupt. [1] https://wiki.analog.com/resources/fpga/peripherals/spi_engine Signed-off-by: Lars-Peter Clausen <lars@metafoo.de> Signed-off-by: Mark Brown <broonie@kernel.org>
2016-02-04 17:13:30 +01:00
}
spi_engine->clk = devm_clk_get(&pdev->dev, "s_axi_aclk");
if (IS_ERR(spi_engine->clk)) {
ret = PTR_ERR(spi_engine->clk);
goto err_put_master;
}
spi_engine->ref_clk = devm_clk_get(&pdev->dev, "spi_clk");
if (IS_ERR(spi_engine->ref_clk)) {
ret = PTR_ERR(spi_engine->ref_clk);
goto err_put_master;
}
ret = clk_prepare_enable(spi_engine->clk);
if (ret)
goto err_put_master;
ret = clk_prepare_enable(spi_engine->ref_clk);
if (ret)
goto err_clk_disable;
writel_relaxed(0x00, spi_engine->base + SPI_ENGINE_REG_RESET);
writel_relaxed(0xff, spi_engine->base + SPI_ENGINE_REG_INT_PENDING);
writel_relaxed(0x00, spi_engine->base + SPI_ENGINE_REG_INT_ENABLE);
ret = request_irq(irq, spi_engine_irq, 0, pdev->name, master);
if (ret)
goto err_ref_clk_disable;
master->dev.of_node = pdev->dev.of_node;
master->mode_bits = SPI_CPOL | SPI_CPHA | SPI_3WIRE;
master->bits_per_word_mask = SPI_BPW_MASK(8);
master->max_speed_hz = clk_get_rate(spi_engine->ref_clk) / 2;
master->transfer_one_message = spi_engine_transfer_one_message;
master->num_chipselect = 8;
ret = spi_register_master(master);
if (ret)
goto err_free_irq;
platform_set_drvdata(pdev, master);
return 0;
err_free_irq:
free_irq(irq, master);
err_ref_clk_disable:
clk_disable_unprepare(spi_engine->ref_clk);
err_clk_disable:
clk_disable_unprepare(spi_engine->clk);
err_put_master:
spi_master_put(master);
return ret;
}
static int spi_engine_remove(struct platform_device *pdev)
{
struct spi_master *master = spi_master_get(platform_get_drvdata(pdev));
spi: Add Analog Devices AXI SPI Engine controller support This patch adds support for the AXI SPI Engine controller which is a FPGA soft-peripheral which is used in some of Analog Devices' reference designs. The AXI SPI Engine controller is part of the SPI Engine framework[1] and allows memory mapped access to the SPI Engine control bus. This allows it to be used as a general purpose software driven SPI controller. The SPI Engine in addition offers some optional advanced acceleration and offloading capabilities, which are not part of this patch though and will be introduced separately. At the core of the SPI Engine framework is a small sort of co-processor that accepts a command stream and turns the commands into low-level SPI transactions. Communication is done through three memory mapped FIFOs in the register map of the AXI SPI Engine peripheral. One FIFO for the command stream and one each for transmit and receive data. The driver translates a spi_message in a command stream and writes it to the peripheral which executes it asynchronously. This allows it to perform very precise timings which are required for some SPI slave devices to achieve maximum performance (e.g. analog-to-digital and digital-to-analog converters). The execution flow is synchronized to the host system by a special synchronize instruction which generates a interrupt. [1] https://wiki.analog.com/resources/fpga/peripherals/spi_engine Signed-off-by: Lars-Peter Clausen <lars@metafoo.de> Signed-off-by: Mark Brown <broonie@kernel.org>
2016-02-04 17:13:30 +01:00
struct spi_engine *spi_engine = spi_master_get_devdata(master);
int irq = platform_get_irq(pdev, 0);
spi_unregister_master(master);
free_irq(irq, master);
spi_master_put(master);
spi: Add Analog Devices AXI SPI Engine controller support This patch adds support for the AXI SPI Engine controller which is a FPGA soft-peripheral which is used in some of Analog Devices' reference designs. The AXI SPI Engine controller is part of the SPI Engine framework[1] and allows memory mapped access to the SPI Engine control bus. This allows it to be used as a general purpose software driven SPI controller. The SPI Engine in addition offers some optional advanced acceleration and offloading capabilities, which are not part of this patch though and will be introduced separately. At the core of the SPI Engine framework is a small sort of co-processor that accepts a command stream and turns the commands into low-level SPI transactions. Communication is done through three memory mapped FIFOs in the register map of the AXI SPI Engine peripheral. One FIFO for the command stream and one each for transmit and receive data. The driver translates a spi_message in a command stream and writes it to the peripheral which executes it asynchronously. This allows it to perform very precise timings which are required for some SPI slave devices to achieve maximum performance (e.g. analog-to-digital and digital-to-analog converters). The execution flow is synchronized to the host system by a special synchronize instruction which generates a interrupt. [1] https://wiki.analog.com/resources/fpga/peripherals/spi_engine Signed-off-by: Lars-Peter Clausen <lars@metafoo.de> Signed-off-by: Mark Brown <broonie@kernel.org>
2016-02-04 17:13:30 +01:00
writel_relaxed(0xff, spi_engine->base + SPI_ENGINE_REG_INT_PENDING);
writel_relaxed(0x00, spi_engine->base + SPI_ENGINE_REG_INT_ENABLE);
writel_relaxed(0x01, spi_engine->base + SPI_ENGINE_REG_RESET);
clk_disable_unprepare(spi_engine->ref_clk);
clk_disable_unprepare(spi_engine->clk);
return 0;
}
static const struct of_device_id spi_engine_match_table[] = {
{ .compatible = "adi,axi-spi-engine-1.00.a" },
{ },
};
MODULE_DEVICE_TABLE(of, spi_engine_match_table);
spi: Add Analog Devices AXI SPI Engine controller support This patch adds support for the AXI SPI Engine controller which is a FPGA soft-peripheral which is used in some of Analog Devices' reference designs. The AXI SPI Engine controller is part of the SPI Engine framework[1] and allows memory mapped access to the SPI Engine control bus. This allows it to be used as a general purpose software driven SPI controller. The SPI Engine in addition offers some optional advanced acceleration and offloading capabilities, which are not part of this patch though and will be introduced separately. At the core of the SPI Engine framework is a small sort of co-processor that accepts a command stream and turns the commands into low-level SPI transactions. Communication is done through three memory mapped FIFOs in the register map of the AXI SPI Engine peripheral. One FIFO for the command stream and one each for transmit and receive data. The driver translates a spi_message in a command stream and writes it to the peripheral which executes it asynchronously. This allows it to perform very precise timings which are required for some SPI slave devices to achieve maximum performance (e.g. analog-to-digital and digital-to-analog converters). The execution flow is synchronized to the host system by a special synchronize instruction which generates a interrupt. [1] https://wiki.analog.com/resources/fpga/peripherals/spi_engine Signed-off-by: Lars-Peter Clausen <lars@metafoo.de> Signed-off-by: Mark Brown <broonie@kernel.org>
2016-02-04 17:13:30 +01:00
static struct platform_driver spi_engine_driver = {
.probe = spi_engine_probe,
.remove = spi_engine_remove,
.driver = {
.name = "spi-engine",
.of_match_table = spi_engine_match_table,
},
};
module_platform_driver(spi_engine_driver);
MODULE_AUTHOR("Lars-Peter Clausen <lars@metafoo.de>");
MODULE_DESCRIPTION("Analog Devices SPI engine peripheral driver");
MODULE_LICENSE("GPL");