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spi-ch341-usb.c
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spi-ch341-usb.c
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/*
* Driver for the CH341 USB to SPI and GPIO adapter
*
* Copyright (c) 2017 Gunar Schorcht ([email protected])
*
* Derived from
*
* i2c-ch341-usb.c Copyright (c) 2016 Tse Lun Bien
* i2c-ch341.c Copyright (c) 2014 Marco Gittler
* i2c-tiny-usb.c Copyright (c) 2006-2007 Till Harbaum ([email protected])
*
* and extended by GPIO and interrupt handling capabilities.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation, version 2.
*/
// uncomment following line to activate kernel debug handling
// #define DEBUG
#define DEBUG_PRINTK
#ifdef DEBUG_PRINTK
#define PRINTK(fmt,...) printk("%s: "fmt"\n", __func__, ##__VA_ARGS__)
#else
#define PRINTK(fmt,...)
#endif
#define CH341_IF_ADDR (&(ch341_dev->usb_if->dev))
#define DEV_ERR(d,f,...) dev_err (d,"%s: "f"\n", __FUNCTION__, ##__VA_ARGS__)
#define DEV_DBG(d,f,...) dev_dbg (d,"%s: "f"\n", __FUNCTION__, ##__VA_ARGS__)
#define DEV_INFO(d,f,...) dev_info(d,"%s: "f"\n", __FUNCTION__, ##__VA_ARGS__)
// check for condition and return with or without err code if it fails
#define CHECK_PARAM_RET(cond,err) if (!(cond)) return err;
#define CHECK_PARAM(cond) if (!(cond)) return;
#include <linux/version.h>
#if LINUX_VERSION_CODE < KERNEL_VERSION(3,10,0)
#error The driver requires at least kernel version 3.10
#else
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/module.h>
#include <linux/types.h>
#include <linux/slab.h>
#include <linux/usb.h>
#include <linux/spi/spi.h>
#include <linux/gpio.h>
#include <linux/irq.h>
/**
* ATTENTION:
*
* CH341_POLL_PERIOD_MS in milliseconds defines the rate at which GPIOs are
* read from CH341 via USB and thus the maximum rate at which changes on
* interrupt driven input ports can be recognized at all.
*
* This value must be at least 10 ms, but should be 20 ms or more (if
* possible) dependent on the performance of your system. Please check your
* syslog for messages like "GPIO poll period is too short by at least %n
* msecs". This message is thrown if the defined CH341_POLL_PERIOD_MS is
* shorter than the time required for one reading of the GPIOs.
*/
#define CH341_POLL_PERIOD_MS 10 // see above
#define CH341_GPIO_NUM_PINS 5 // Number of GPIO pins, DO NOT CHANGE
#define CH341_USB_MAX_BULK_SIZE 32 // CH341A wMaxPacketSize for ep_02 and ep_82
#define CH341_USB_MAX_INTR_SIZE 8 // CH341A wMaxPacketSize for ep_81
#define CH341_CMD_SPI_STREAM 0xA8 // SPI command
#define CH341_CMD_UIO_STREAM 0xAB // UIO command
#define CH341_CMD_UIO_STM_IN 0x00 // UIO interface IN command (D0~D7)
#define CH341_CMD_UIO_STM_OUT 0x80 // UIO interface OUT command (D0~D5)
#define CH341_CMD_UIO_STM_DIR 0x40 // UIO interface DIR command (D0~D5)
#define CH341_CMD_UIO_STM_END 0x20 // UIO interface END command
#define CH341_CMD_UIO_STM_US 0xc0 // UIO interface US command
#define CH341_SPI_MAX_NUM_DEVICES 3
#define CH341_SPI_BUS_NUM 0
#define CH341_SPI_MODALIAS "spidev"
#define CH341_SPI_MODE SPI_MODE_0
#define CH341_SPI_MIN_FREQ 400
#define CH341_SPI_MAX_FREQ 1e6
#define CH341_SPI_MIN_BITS_PER_WORD 4
#define CH341_SPI_MAX_BITS_PER_WORD 32
#define CH341_PIN_MODE_OUT 0
#define CH341_PIN_MODE_IN 1
#define CH341_PIN_MODE_CS 2
#define CH341_OK 0
/**
*
* Change the default values in *ch341_board_config* for your configuraton
*
* Configurable are:
*
* - Pin 15 (D0/CS0 ) as input/output/CS (CH341_PIN_MODE_IN/CH341_PIN_MODE_OUT/CH341_PIN_MODE_CS)
* - Pin 16 (D1/CS1 ) as input/output/CS (CH341_PIN_MODE_IN/CH341_PIN_MODE_OUT/CH341_PIN_MODE_CS)
* - Pin 17 (D2/CS2 ) as input/output/CS (CH341_PIN_MODE_IN/CH341_PIN_MODE_OUT/CH341_PIN_MODE_CS)
* - Pin 19 (D4/DOUT2) as input/output (CH341_PIN_MODE_IN/CH341_PIN_MODE_OUT)
* - Pin 21 (D6/DIN2 ) as input (CH341_PIN_MODE_IN)
*
* Pins 18, 20, 22 have fix configuraton and are used as SPI signals.
*/
struct ch341_pin_config {
uint8_t pin; // pin number of CH341 chip
uint8_t mode; // GPIO mode
char* name; // GPIO name
bool hwirq; // connected to hardware interrupt (only one pin can have true)
};
struct ch341_pin_config ch341_board_config[CH341_GPIO_NUM_PINS] =
{
// pin GPIO mode GPIO name hwirq
{ 15, CH341_PIN_MODE_CS , "cs0" , 0 }, // used as CS0
{ 16, CH341_PIN_MODE_CS , "cs1" , 0 }, // used as CS1
{ 17, CH341_PIN_MODE_CS , "cs2" , 0 }, // used as CS2
{ 19, CH341_PIN_MODE_IN , "gpio4" , 1 }, // used as input with hardware IRQ
{ 21, CH341_PIN_MODE_IN , "gpio5" , 0 } // used as input
};
static struct spi_board_info ch341_spi_devices[CH341_SPI_MAX_NUM_DEVICES];
struct spi_board_info ch341_spi_device_template =
{
.modalias = "spidev",
.max_speed_hz = CH341_SPI_MAX_FREQ,
.bus_num = 0,
.chip_select = 0,
.mode = SPI_MODE_0,
};
// device specific structure
struct ch341_device
{
// USB device description
struct usb_device* usb_dev; // usb device
struct usb_interface* usb_if; // usb interface
struct usb_endpoint_descriptor *ep_in; // usb endpoint bulk in
struct usb_endpoint_descriptor *ep_out; // usb endpoint bulk out
struct usb_endpoint_descriptor *ep_intr; // usb endpoint interrupt in
uint8_t in_buf [CH341_USB_MAX_BULK_SIZE]; // usb input buffer
uint8_t out_buf [CH341_USB_MAX_BULK_SIZE]; // usb outpu buffer
uint8_t intr_buf[CH341_USB_MAX_INTR_SIZE]; // usb interrupt buffer
struct urb* intr_urb;
// SPI device description
struct spi_master* master; // spi master
struct spi_device* slaves[CH341_SPI_MAX_NUM_DEVICES];
int slave_num;
// GPIO device description
struct gpio_chip gpio; // chip descriptor for GPIOs
uint8_t gpio_num; // number of pins used as GPIOs
uint8_t gpio_mask; // configuratoin mask defines IN/OUT pins
uint8_t gpio_io_data; // current value of CH341 I/O register
struct task_struct * gpio_thread; // GPIO poll thread
struct ch341_pin_config* gpio_pins [CH341_GPIO_NUM_PINS]; // pin configurations (gpio_num elements)
uint8_t gpio_bits [CH341_GPIO_NUM_PINS]; // bit of I/O data byte (gpio_num elements)
uint8_t gpio_values [CH341_GPIO_NUM_PINS]; // current values (gpio_num elements)
char* gpio_names [CH341_GPIO_NUM_PINS]; // pin names (gpio_num elements)
int gpio_irq_map[CH341_GPIO_NUM_PINS]; // GPIO to IRQ map (gpio_num elements)
// IRQ device description
struct irq_chip irq; // chip descriptor for IRQs
uint8_t irq_num; // number of pins with IRQs
int irq_base; // base IRQ allocated
struct irq_desc * irq_descs [CH341_GPIO_NUM_PINS]; // IRQ descriptors used (irq_num elements)
int irq_types [CH341_GPIO_NUM_PINS]; // IRQ types (irq_num elements)
bool irq_enabled [CH341_GPIO_NUM_PINS]; // IRQ enabled flag (irq_num elements)
int irq_gpio_map [CH341_GPIO_NUM_PINS]; // IRQ to GPIO pin map (irq_num elements)
int irq_hw; // IRQ for GPIO with hardware IRQ (default -1)
};
// ----- variables configurable during runtime ---------------------------
static uint poll_period = CH341_POLL_PERIOD_MS; // module parameter poll period
// ----- function prototypes ---------------------------------------------
static int ch341_usb_transfer (struct ch341_device *dev, int out_len, int in_len);
// ----- board configuration layer begin ---------------------------------
static int ch341_cfg_probe (struct ch341_device* ch341_dev)
{
struct ch341_pin_config* cfg;
int i;
CHECK_PARAM_RET (ch341_dev, -EINVAL);
ch341_dev->gpio_mask = 0x3f; // default - IN: MISO, IN2 - OUT: MOSI, OUT2, SCK, CS#;
ch341_dev->gpio_num = 0;
ch341_dev->gpio_thread = 0;
ch341_dev->irq_num = 0;
ch341_dev->irq_base = 0;
ch341_dev->irq_hw = -1;
for (i = 0; i < CH341_GPIO_NUM_PINS; i++)
{
cfg = ch341_board_config + i;
if (cfg->pin == 0)
continue;
// --- check correct pin configuration ------------
// is pin configurable at all
if (cfg->pin < 15 || (cfg->pin > 17 && cfg->pin != 19 && cfg->pin != 21))
{
DEV_ERR(CH341_IF_ADDR, "pin %d: is not configurable", cfg->pin);
return -EINVAL;
}
// is pin configured correctly as input in case of pin 21
else if (cfg->pin == 21 && cfg->mode != CH341_PIN_MODE_IN)
{
DEV_ERR(CH341_IF_ADDR, "pin 21: must be an input");
return -EINVAL;
}
// is pin configurable as CS signal
else if (cfg->pin > 17 && cfg->mode == CH341_PIN_MODE_CS)
{
DEV_ERR(CH341_IF_ADDR, "pin %d: can't be used as CS signal", cfg->pin);
return -EINVAL;
}
// --- read in pin configuration
if (cfg->mode == CH341_PIN_MODE_CS)
{
// if pin is CS signal, set SPI slave device configuration
ch341_spi_devices[ch341_dev->slave_num] = ch341_spi_device_template;
ch341_spi_devices[ch341_dev->slave_num].bus_num = CH341_SPI_BUS_NUM;
ch341_spi_devices[ch341_dev->slave_num].mode = CH341_SPI_MODE;
ch341_spi_devices[ch341_dev->slave_num].chip_select = cfg->pin - 15;
DEV_INFO (CH341_IF_ADDR, "output %s SPI slave with cs=%d",
cfg->name, ch341_spi_devices[ch341_dev->slave_num].chip_select);
ch341_dev->slave_num++;
}
else // CH341_PIN_MODE_IN || CH341_PIN_MODE_OUT
{
// if pin is not configured as CS signal, set GPIO configuration
ch341_dev->gpio_names [ch341_dev->gpio_num] = cfg->name;
ch341_dev->gpio_pins [ch341_dev->gpio_num] = cfg;
ch341_dev->gpio_irq_map[ch341_dev->gpio_num] = -1; // no valid IRQ
// map CH341 pin to bit D0...D7 in the CH341 I/O data byte
switch (ch341_board_config[i].pin)
{
case 15: ch341_dev->gpio_bits[ch341_dev->gpio_num] = 0x01; break; // D0/CS0 (default OUT)
case 16: ch341_dev->gpio_bits[ch341_dev->gpio_num] = 0x02; break; // D1/CS1 (default OUT)
case 17: ch341_dev->gpio_bits[ch341_dev->gpio_num] = 0x04; break; // D2/CS2 (default OUT)
case 19: ch341_dev->gpio_bits[ch341_dev->gpio_num] = 0x10; break; // D4/DOUT2 (default OUT)
case 21: ch341_dev->gpio_bits[ch341_dev->gpio_num] = 0x40; break; // D6/DIN2 (default IN )
}
// GPIO pins can generate IRQs when set to input mode
ch341_dev->gpio_irq_map[ch341_dev->gpio_num] = ch341_dev->irq_num;
ch341_dev->irq_gpio_map[ch341_dev->irq_num] = ch341_dev->gpio_num;
if (cfg->hwirq)
{
if (ch341_dev->irq_hw != -1)
{
DEV_ERR(CH341_IF_ADDR,
"pin %d: only one GPIO can be connected to the hardware IRQ",
cfg->pin);
return -EINVAL;
}
ch341_dev->irq_hw = ch341_dev->irq_num;
}
if (cfg->mode == CH341_PIN_MODE_IN)
// if pin is INPUT, it has to be masked out in GPIO direction mask
ch341_dev->gpio_mask &= ~ch341_dev->gpio_bits[ch341_dev->gpio_num];
DEV_INFO (CH341_IF_ADDR, "%s %s gpio=%d irq=%d %s",
cfg->mode == CH341_PIN_MODE_IN ? "input " : "output",
cfg->name, ch341_dev->gpio_num, ch341_dev->irq_num,
cfg->hwirq ? "(hwirq)" : "");
ch341_dev->irq_num++;
ch341_dev->gpio_num++;
}
}
if (ch341_dev->slave_num == 0)
{
DEV_ERR(CH341_IF_ADDR, "at least one of the pins 15 ... 17 has to be configured as CS signal");
return -EINVAL;
}
return CH341_OK;
}
static void ch341_cfg_remove (struct ch341_device* ch341_dev)
{
CHECK_PARAM (ch341_dev);
return;
}
// ----- board configuration layer end -----------------------------------
// ----- spi layer begin -------------------------------------------------
static struct mutex ch341_lock;
#define ch341_spi_maser_to_dev(m) *((struct ch341_device**)spi_master_get_devdata(m))
static int ch341_spi_read_inputs (struct ch341_device* ch341_dev)
{
int result;
mutex_lock (&ch341_lock);
ch341_dev->out_buf[0] = CH341_CMD_UIO_STREAM;
ch341_dev->out_buf[1] = CH341_CMD_UIO_STM_DIR | ch341_dev->gpio_mask;
ch341_dev->out_buf[2] = CH341_CMD_UIO_STM_IN;
ch341_dev->out_buf[3] = CH341_CMD_UIO_STM_END;
result = ch341_usb_transfer(ch341_dev, 4, 1);
ch341_dev->gpio_io_data &= ch341_dev->gpio_mask;
ch341_dev->gpio_io_data |= ch341_dev->in_buf[0] & ~ch341_dev->gpio_mask;
mutex_unlock (&ch341_lock);
return (result < 0) ? result : CH341_OK;
}
static int ch341_spi_write_outputs (struct ch341_device* ch341_dev)
{
int result;
mutex_lock (&ch341_lock);
ch341_dev->out_buf[0] = CH341_CMD_UIO_STREAM;
ch341_dev->out_buf[1] = CH341_CMD_UIO_STM_DIR | ch341_dev->gpio_mask;
ch341_dev->out_buf[2] = CH341_CMD_UIO_STM_OUT | (ch341_dev->gpio_io_data & ch341_dev->gpio_mask);
ch341_dev->out_buf[3] = CH341_CMD_UIO_STM_END;
// DEV_DBG(CH341_IF_ADDR, "%02x", ch341_dev->out_buf[2]);
result = ch341_usb_transfer(ch341_dev, 4, 0);
mutex_unlock (&ch341_lock);
return (result < 0) ? result : CH341_OK;
}
static uint8_t ch341_spi_swap_byte(const uint8_t byte)
{
uint8_t orig = byte;
uint8_t swap = 0;
int i;
for (i = 0; i < 8; ++i)
{
swap = swap << 1;
swap |= (orig & 1);
orig = orig >> 1;
}
return swap;
}
static const int cs_bits[CH341_SPI_MAX_NUM_DEVICES] = { 0x01, 0x02, 0x04 };
static int ch341_spi_set_cs (struct spi_device *spi, bool active)
{
struct ch341_device* ch341_dev;
int result;
CHECK_PARAM_RET (spi, -EINVAL);
CHECK_PARAM_RET (ch341_dev = ch341_spi_maser_to_dev(spi->master), -EINVAL);
// DEV_DBG (CH341_IF_ADDR, "active %s", active ? "true" : "false");
if (spi->chip_select > CH341_SPI_MAX_NUM_DEVICES)
{
DEV_ERR (CH341_IF_ADDR, "invalid CS value %d, 0~%d are available",
spi->chip_select, CH341_SPI_MAX_NUM_DEVICES-1);
return -EINVAL;
}
if (active)
ch341_dev->gpio_io_data &= ~cs_bits[spi->chip_select];
else
ch341_dev->gpio_io_data |= cs_bits[spi->chip_select];
ch341_dev->out_buf[0] = CH341_CMD_UIO_STREAM;
ch341_dev->out_buf[1] = CH341_CMD_UIO_STM_DIR | ch341_dev->gpio_mask;
ch341_dev->out_buf[2] = CH341_CMD_UIO_STM_OUT | (ch341_dev->gpio_io_data & ch341_dev->gpio_mask);
ch341_dev->out_buf[3] = CH341_CMD_UIO_STM_END;
result = ch341_usb_transfer(ch341_dev, 4, 0);
return (result < 0) ? result : CH341_OK;
}
// Implementation of bit banging protocol uses following IOs to be compatible
// with the hardware SPI interface
//
// D7 D6 D5 D4 D3 D2 D1 D0
// MISO IN2 MOSI OUT2 SCK CS2 CS1 CS0
static int ch341_spi_bitbang (struct ch341_device* ch341_dev,
struct spi_device *spi,
const uint8_t* tx, uint8_t* rx, int len)
{
uint8_t byte, bit;
uint8_t* io = ch341_dev->out_buf;
int result = 0;
int k = 0;
int i, b;
// CPOL=0, CPHA=0 data must be stable while clock is high, can be changed while clock is low
// mode 0 data sampled on raising clock edge
//
// CPOL=0, CPHA=1 data must be stable while clock is low, can be changed while clock is high
// mode=1 data sampled on falling clock edge
//
// CPOL=1, CPHA=0 data must be stable while clock is low, can be changed while clock is high
// mode=2 data sampled on falling clock edge
//
// CPOL=1, CPHA=1 data must be stable while clock is high, can be changed while clock is low
// mode=3 data sampled on raising clock edge
uint8_t SCK_H = 0x08;
uint8_t SCK_L = 0;
uint8_t CPOL = (spi->mode & SPI_CPOL) ? 0x08 : 0;
uint8_t CS_H = cs_bits[spi->chip_select];
uint8_t CS_L = 0;
uint8_t MOSI_H = 0x20;
uint8_t MASK = ch341_dev->gpio_mask;
uint8_t DATA = ch341_dev->gpio_io_data & ch341_dev->gpio_mask;
uint8_t mode = spi->mode & SPI_MODE_3;
bool lsb = spi->mode & SPI_LSB_FIRST;
// DEV_DBG (CH341_IF_ADDR, "start");
// mask SPI GPIO data
DATA &= ~MOSI_H & ~SCK_H & ~CS_H;
k = 0;
io[k++] = CH341_CMD_UIO_STREAM;
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_H | CPOL; // set defaults CS#=HIGH, SCK=CPOL
io[k++] = CH341_CMD_UIO_STM_DIR | MASK; // input: MISO, IN2; output MOSI, OUT2, SCK, CS#;
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_L | CPOL; // start with CS0=LOW, SCK=CPOL
io[k++] = CH341_CMD_UIO_STM_END;
if ((result = ch341_usb_transfer(ch341_dev, k, 0)) < 0)
return result;
for (b = 0; b < len; b++)
{
k = 0;
io[k++] = CH341_CMD_UIO_STREAM;
byte = lsb ? ch341_spi_swap_byte(tx[b]) : tx[b];
for (i = 0; i < 8; i++)
{
bit = byte & 0x80 ? 0x20 : 0; // lsb
byte = byte << 1;
if (mode == SPI_MODE_0 || mode == SPI_MODE_3)
{
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_L | SCK_L | bit; // keep CS0=LOW, set SCK=LOW , set MOSI
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_L | SCK_H | bit; // keep CS0=LOW, set SCK=HIGH, keep MOSI
io[k++] = CH341_CMD_UIO_STM_IN; // read MISO
}
else
{
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_L | SCK_L | bit; // keep CS0=LOW, set SCK=HIGH, set MOSI
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_L | SCK_H | bit; // keep CS0=LOW, set SCK=LOW , keep MOSI
io[k++] = CH341_CMD_UIO_STM_IN; // read MISO
}
}
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_L | CPOL; // keep CS0=LOW, SCK=CPOL, MOSI=LOW
io[k++] = CH341_CMD_UIO_STM_END;
if ((result = ch341_usb_transfer(ch341_dev, k, 8)) < 0)
return result;
byte = 0;
for (i = 0; i < 8; i++)
{
byte = byte << 1;
byte = byte | ((ch341_dev->in_buf[i] & 0x80) ? 1 : 0);
}
rx[b] = lsb ? ch341_spi_swap_byte(byte) : byte;
}
k = 0;
io[k++] = CH341_CMD_UIO_STREAM;
io[k++] = CH341_CMD_UIO_STM_OUT | DATA | CS_H | CPOL; // default status: CS#=HIGH, SCK=CPOL
io[k++] = CH341_CMD_UIO_STM_END;
if ((result = ch341_usb_transfer(ch341_dev, k, 0)) < 0)
return result;
// save last I/O data byte
DATA = ch341_dev->gpio_io_data;
DATA &= ~MOSI_H & ~SCK_H & ~CS_H;
DATA |= CS_H | CPOL;
// DEV_DBG (CH341_IF_ADDR, "done");
return 0;
}
static int ch341_spi_transfer_one(struct spi_master *master,
struct spi_device *spi,
struct spi_transfer* t)
{
struct ch341_device* ch341_dev = ch341_spi_maser_to_dev(spi->master);
const uint8_t* tx;
uint8_t* rx;
bool lsb;
int result = 0;
int i;
CHECK_PARAM_RET (ch341_dev, EIO);
CHECK_PARAM_RET (master , EIO)
CHECK_PARAM_RET (spi , EIO)
CHECK_PARAM_RET (t , EIO);
CHECK_PARAM_RET (t->len <= CH341_USB_MAX_BULK_SIZE, EIO);
// DEV_DBG (CH341_IF_ADDR, "");
mutex_lock (&ch341_lock);
// use slow bitbang implementation for SPI_MODE_1, SPI_MODE_2 and SPI_MODE_3
if (spi->mode & SPI_MODE_3)
result = ch341_spi_bitbang (ch341_dev, spi, t->tx_buf, t->rx_buf, t->len);
// otherwise the faster hardware implementation
else
{
lsb = spi->mode & SPI_LSB_FIRST;
tx = t->tx_buf;
rx = t->rx_buf;
// activate cs
ch341_spi_set_cs (spi, true);
// fill output buffer with command and output data, controller expects lsb first
ch341_dev->out_buf[0] = CH341_CMD_SPI_STREAM;
for (i = 0; i < t->len; i++)
ch341_dev->out_buf[i+1] = lsb ? tx[i] : ch341_spi_swap_byte(tx[i]);
// transfer output and input data
result = ch341_usb_transfer(ch341_dev, t->len + 1, t->len);
// deactivate cs
ch341_spi_set_cs (spi, false);
// fill input data with input buffer, controller delivers lsb first
if (result >= 0 && rx)
for (i = 0; i < t->len; i++)
rx[i] = lsb ? ch341_dev->in_buf[i] : ch341_spi_swap_byte(ch341_dev->in_buf[i]);
}
spi_finalize_current_transfer(master);
mutex_unlock (&ch341_lock);
return result;
}
static int ch341_spi_probe (struct ch341_device* ch341_dev)
{
int bus = 0;
int result;
int i;
CHECK_PARAM_RET (ch341_dev, -EINVAL);
DEV_DBG (CH341_IF_ADDR, "start");
// search for next free bus number
while ((ch341_dev->master = spi_busnum_to_master(bus)))
{
// returns a refcounted pointer to an existing master
spi_master_put (ch341_dev->master);
bus++;
}
// allocate a new SPI master with a pointer to ch341_device as device data
ch341_dev->master = spi_alloc_master(CH341_IF_ADDR, sizeof(struct ch341_device*));
if (!ch341_dev->master)
{
DEV_ERR (CH341_IF_ADDR, "SPI master allocation failed");
return -ENOMEM;
}
// save the pointer to ch341_dev in the SPI master device data field
ch341_spi_maser_to_dev (ch341_dev->master) = ch341_dev;
DEV_INFO (CH341_IF_ADDR, "SPI master connected to SPI bus %d", bus);
// set SPI master configuration
ch341_dev->master->bus_num = bus;
ch341_dev->master->num_chipselect = CH341_SPI_MAX_NUM_DEVICES;
ch341_dev->master->mode_bits = SPI_MODE_3 | SPI_LSB_FIRST;
ch341_dev->master->flags = SPI_MASTER_MUST_RX | SPI_MASTER_MUST_TX;
#if LINUX_VERSION_CODE <= KERNEL_VERSION(5,0,0)
ch341_dev->master->bits_per_word_mask = SPI_BIT_MASK(8);
#else
ch341_dev->master->bits_per_word_mask = SPI_BPW_MASK(8);
#endif
ch341_dev->master->transfer_one = ch341_spi_transfer_one;
ch341_dev->master->max_speed_hz = CH341_SPI_MAX_FREQ;
ch341_dev->master->min_speed_hz = CH341_SPI_MIN_FREQ;
// register the new master
if ((result = spi_register_master (ch341_dev->master)))
{
DEV_ERR(CH341_IF_ADDR, "could not register SPI master");
spi_master_put(ch341_dev->master);
// in case of error, reset the master to avoid crash during free
ch341_dev->master = 0;
return result;
}
// create SPI slaves
for (i = 0; i < ch341_dev->slave_num; i++)
{
ch341_spi_devices[i].bus_num = bus;
if ((ch341_dev->slaves[i] = spi_new_device(ch341_dev->master, &ch341_spi_devices[i])))
{
DEV_INFO (CH341_IF_ADDR, "SPI device /dev/spidev%d.%d created",
bus, ch341_spi_devices[i].chip_select);
ch341_spi_set_cs (ch341_dev->slaves[i], false);
}
}
mutex_init (&ch341_lock);
DEV_DBG (CH341_IF_ADDR, "done");
return CH341_OK;
}
static void ch341_spi_remove (struct ch341_device* ch341_dev)
{
int i;
CHECK_PARAM (ch341_dev);
for (i = 0; i < ch341_dev->slave_num; i++)
if (ch341_dev->slaves[i])
spi_unregister_device (ch341_dev->slaves[i]);
if (ch341_dev->master)
{
spi_unregister_master (ch341_dev->master);
spi_master_put (ch341_dev->master);
}
return;
}
// ----- spi layer end ---------------------------------------------------
// ----- irq layer begin -------------------------------------------------
void ch341_irq_enable_disable (struct irq_data *data, bool enable)
{
struct ch341_device *ch341_dev;
int irq;
CHECK_PARAM (data && (ch341_dev = irq_data_get_irq_chip_data(data)));
// calculate local IRQ
irq = data->irq - ch341_dev->irq_base;
// valid IRQ is in range 0 ... ch341_dev->irq_num-1, invalid IRQ is -1
if (irq < 0 || irq >= ch341_dev->irq_num) return;
// enable local IRQ
ch341_dev->irq_enabled[irq] = enable;
DEV_INFO (CH341_IF_ADDR, "irq=%d enabled=%d",
data->irq, ch341_dev->irq_enabled[irq] ? 1 : 0);
}
void ch341_irq_enable (struct irq_data *data)
{
ch341_irq_enable_disable (data, true);
}
void ch341_irq_disable (struct irq_data *data)
{
ch341_irq_enable_disable (data, false);
}
int ch341_irq_set_type (struct irq_data *data, unsigned int type)
{
struct ch341_device *ch341_dev;
int irq;
CHECK_PARAM_RET (data && (ch341_dev = irq_data_get_irq_chip_data(data)), -EINVAL);
// calculate local IRQ
irq = data->irq - ch341_dev->irq_base;
// valid IRQ is in range 0 ... ch341_dev->irq_num-1, invalid IRQ is -1
if (irq < 0 || irq >= ch341_dev->irq_num) return -EINVAL;
ch341_dev->irq_types[irq] = type;
DEV_INFO (CH341_IF_ADDR, "irq=%d flow_type=%d", data->irq, type);
return CH341_OK;
}
static int ch341_irq_check (struct ch341_device* ch341_dev, uint8_t irq,
uint8_t old, uint8_t new, bool hardware)
{
int type;
CHECK_PARAM_RET (old != new, CH341_OK)
CHECK_PARAM_RET (ch341_dev, -EINVAL);
CHECK_PARAM_RET (irq < ch341_dev->irq_num, -EINVAL);
// valid IRQ is in range 0 ... ch341_dev->irq_num-1, invalid IRQ is -1
if (irq < 0 || irq >= ch341_dev->irq_num) return -EINVAL;
// if IRQ is disabled, just return with success
if (!ch341_dev->irq_enabled[irq]) return CH341_OK;
type = ch341_dev->irq_types[irq];
// for software IRQs dont check if IRQ is the hardware IRQ for rising edges
if (!hardware && irq == ch341_dev->irq_hw && new > old)
return CH341_OK;
if ((type & IRQ_TYPE_EDGE_FALLING && old > new) ||
(type & IRQ_TYPE_EDGE_RISING && new > old))
{
// DEV_DBG (CH341_IF_ADDR, "%s irq=%d %d %s",
// hardware ? "hardware" : "software",
// irq, type, (old > new) ? "falling" : "rising");
#if LINUX_VERSION_CODE >= KERNEL_VERSION(4,3,0)
handle_simple_irq (ch341_dev->irq_descs[irq]);
#else
handle_simple_irq (ch341_dev->irq_base+irq, ch341_dev->irq_descs[irq]);
#endif
}
return CH341_OK;
}
static int ch341_irq_probe (struct ch341_device* ch341_dev)
{
int i;
int result;
CHECK_PARAM_RET (ch341_dev, -EINVAL);
DEV_DBG (CH341_IF_ADDR, "start");
ch341_dev->irq.name = "ch341";
ch341_dev->irq.irq_enable = ch341_irq_enable;
ch341_dev->irq.irq_disable = ch341_irq_disable;
ch341_dev->irq.irq_set_type = ch341_irq_set_type;
if (!ch341_dev->irq_num) return CH341_OK;
if ((result = irq_alloc_descs(-1, 0, ch341_dev->irq_num, 0)) < 0)
{
DEV_ERR (CH341_IF_ADDR, "failed to allocate IRQ descriptors");
return result;
}
ch341_dev->irq_base = result;
DEV_DBG (CH341_IF_ADDR, "irq_base=%d", ch341_dev->irq_base);
for (i = 0; i < ch341_dev->irq_num; i++)
{
ch341_dev->irq_descs[i] = irq_to_desc(ch341_dev->irq_base + i);
ch341_dev->irq_enabled[i] = false;
irq_set_chip (ch341_dev->irq_base + i, &ch341_dev->irq);
irq_set_chip_data (ch341_dev->irq_base + i, ch341_dev);
irq_clear_status_flags(ch341_dev->irq_base + i, IRQ_NOREQUEST | IRQ_NOPROBE);
}
DEV_DBG (CH341_IF_ADDR, "done");
return CH341_OK;
}
static void ch341_irq_remove (struct ch341_device* ch341_dev)
{
CHECK_PARAM (ch341_dev);
if (ch341_dev->irq_base)
irq_free_descs (ch341_dev->irq_base, ch341_dev->irq_num);
return;
}
// ----- irq layer end ---------------------------------------------------
// ----- gpio layer begin ------------------------------------------------
void ch341_gpio_read_inputs (struct ch341_device* ch341_dev)
{
uint8_t old_io_data;
uint8_t old_value;
uint8_t new_value;
uint8_t gpio;
int i;
CHECK_PARAM (ch341_dev);
// DEV_DBG (CH341_IF_ADDR, "start");
// save old value
old_io_data = ch341_dev->gpio_io_data;
// read current values
ch341_spi_read_inputs (ch341_dev);
for (i = 0; i < ch341_dev->irq_num; i++)
{
// determine local GPIO for each IRQ
gpio = ch341_dev->irq_gpio_map[i];
// determin old an new value of the bit
old_value = (old_io_data & ch341_dev->gpio_bits[gpio]) ? 1 : 0;
new_value = (ch341_dev->gpio_io_data & ch341_dev->gpio_bits[gpio]) ? 1 : 0;
// check for interrupt
ch341_irq_check (ch341_dev, i, old_value, new_value, false);
}
// DEV_DBG (CH341_IF_ADDR, "done");
}
// #define CH341_POLL_WITH_SLEEP
static int ch341_gpio_poll_function (void* argument)
{
struct ch341_device* ch341_dev = (struct ch341_device*)argument;
unsigned int next_poll_ms = jiffies_to_msecs(jiffies);
unsigned int jiffies_ms;
int drift_ms = 0;
int corr_ms = 0;
int sleep_ms = 0;
CHECK_PARAM_RET (ch341_dev, -EINVAL);
DEV_DBG (CH341_IF_ADDR, "start");
while (!kthread_should_stop())
{
// current time in ms
jiffies_ms = jiffies_to_msecs(jiffies);
drift_ms = jiffies_ms - next_poll_ms;
if (poll_period == 0)
{
poll_period = CH341_POLL_PERIOD_MS;
DEV_ERR (CH341_IF_ADDR,
"Poll period 0 ms is invalid, set back to the default of %d ms",
CH341_POLL_PERIOD_MS);
}
if (drift_ms < 0)
{
// period was to short, increase corr_ms by 1 ms
// DEV_DBG (CH341_IF_ADDR, "polling GPIO is %u ms too early", -drift_ms);
corr_ms = (corr_ms > 0) ? corr_ms - 1 : 0;
}
else if (drift_ms > 0 && drift_ms < poll_period)
{
// period was to long, decrease corr_ms by 1 ms
// DEV_DBG (CH341_IF_ADDR, "polling GPIO is %u ms too late", drift_ms);
corr_ms = (corr_ms < poll_period) ? corr_ms + 1 : 0;
}
next_poll_ms = jiffies_ms + poll_period;
// DEV_DBG (CH341_IF_ADDR, "read CH341 GPIOs");
ch341_gpio_read_inputs (ch341_dev);
jiffies_ms = jiffies_to_msecs(jiffies);
// if GPIO read took longer than poll period, do not sleep
if (jiffies_ms > next_poll_ms)
{
DEV_ERR (CH341_IF_ADDR,
"GPIO poll period is too short by at least %u msecs",
jiffies_ms - next_poll_ms);
}
else
{
sleep_ms = next_poll_ms - jiffies_ms - corr_ms;
#ifdef CH341_POLL_WITH_SLEEP
msleep ((sleep_ms <= 0) ? 1 : sleep_ms);
#else
set_current_state(TASK_UNINTERRUPTIBLE);
schedule_timeout(msecs_to_jiffies((sleep_ms <= 0) ? 1 : sleep_ms));
#endif
}
}
#ifndef CH341_POLL_WITH_SLEEP
__set_current_state(TASK_RUNNING);
#endif
DEV_DBG (CH341_IF_ADDR, "stop");
return 0;
}
int ch341_gpio_get (struct gpio_chip *chip, unsigned offset)
{
#if LINUX_VERSION_CODE >= KERNEL_VERSION(4,5,0)
struct ch341_device* ch341_dev = (struct ch341_device*)gpiochip_get_data(chip);
#else
struct ch341_device* ch341_dev = container_of(chip, struct ch341_device, gpio);
#endif
int value;
CHECK_PARAM_RET (ch341_dev, -EINVAL);
CHECK_PARAM_RET (offset < ch341_dev->gpio_num, -EINVAL);
value = (ch341_dev->gpio_io_data & ch341_dev->gpio_bits[offset]) ? 1 : 0;
// DEV_DBG (CH341_IF_ADDR, "offset=%u value=%d io_data=%02x",
// offset, value, ch341_dev->gpio_io_data);
return value;
}
// FIXME: not tested at the moment (will be introduced with kernel 4.15.0)
int ch341_gpio_get_multiple (struct gpio_chip *chip,
unsigned long *mask, unsigned long *bits)
{
#if LINUX_VERSION_CODE >= KERNEL_VERSION(4,5,0)
struct ch341_device* ch341_dev = (struct ch341_device*)gpiochip_get_data(chip);
#else
struct ch341_device* ch341_dev = container_of(chip, struct ch341_device, gpio);
#endif
int i;
CHECK_PARAM_RET (ch341_dev, -EINVAL);
CHECK_PARAM_RET (mask, -EINVAL);
CHECK_PARAM_RET (bits, -EINVAL);
for (i = 0; i < ch341_dev->gpio_num; i++)
if (*mask & (1 << i))
{
*bits &= ~(1 << i);
*bits |= (((ch341_dev->gpio_io_data & ch341_dev->gpio_bits[i]) ? 1 : 0) << i);
}
// DEV_DBG (CH341_IF_ADDR, "mask=%08lx bit=%08lx io_data=%02x",
// *mask, *bits, ch341_dev->gpio_io_data);
return CH341_OK;
}
void ch341_gpio_set (struct gpio_chip *chip, unsigned offset, int value)
{
#if LINUX_VERSION_CODE >= KERNEL_VERSION(4,5,0)
struct ch341_device* ch341_dev = (struct ch341_device*)gpiochip_get_data(chip);
#else
struct ch341_device* ch341_dev = container_of(chip, struct ch341_device, gpio);
#endif
CHECK_PARAM (ch341_dev);
CHECK_PARAM (offset < ch341_dev->gpio_num);
if (value)
ch341_dev->gpio_io_data |= ch341_dev->gpio_bits[offset];
else
ch341_dev->gpio_io_data &= ~ch341_dev->gpio_bits[offset];