satip-axe/kernel/drivers/char/lirc/lirc_stm.c
2015-03-26 17:24:57 +01:00

1618 lines
46 KiB
C

/*
* LIRC plugin for the STMicroelectronics IRDA devices
*
* Copyright (C) 2004-2008 STMicroelectronics
*
* June 2004: first implementation for a 2.4 Linux kernel
* Giuseppe Cavallaro <peppe.cavallaro@st.com>
* Marc 2005: review to support pure raw mode and to adapt to Linux 2.6
* Giuseppe Cavallaro <peppe.cavallaro@st.com>
* June 2005: Change to a MODE2 receive driver and made into a generic
* ST driver.
* Carl Shaw <carl.shaw@st.com>
* July 2005: fix STB7100 MODE2 implementation and improve performance
* of STm8000 version. <carl.shaw@st.com>
* Aug 2005: Added clock autoconfiguration support. Fixed module exit code.
* Added UHF support (kernel build only).
* Carl Shaw <carl.shaw@st.com>
* Sep 2005: Added first transmit support
* Added ability to set rxpolarity register
* Angelo Castello <angelo.castello@st.com>
* and Carl Shaw <carl.shaw@st.com>
* Oct 2005: Added 7100 transmit
* Added carrier width configuration
* Carl Shaw <carl.shaw@st.com>
* Sept 2006: Update:
* fix timing issues (bugzilla 764)
* Thomas Betker <thomas.betker@siemens.com>
* allocate PIO pins in driver
* update transmit
* improve fault handling on init
* Carl Shaw <carl.shaw@st.com>
* Oct 2007: Added both lirc-0.8.2 common interface and integrated out IRB driver
* to be working for linux-2.6.23-rc7. Removed old platform support...
* Sti5528 STb8000. Added new IR rx intq mechanism to reduce the amount
* intq needed to identify one button. Fix TX transmission loop setting up
* correctly the irq clean register.
* Angelo Castello <angelo.castello@st.com>
* Nov 2007: Moved here all the platform
* dependences leaving clear of this task the common interface. (lirc_dev.c)
* Code cleaning and optimization.
* Angelo Castello <angelo.castello@st.com>
* Dec 2007: Added device resource management support.
* Angelo Castello <angelo.castello@st.com>
* Mar 2008: Fix UHF support and general tidy up
* Carl Shaw <carl.shaw@st.com>
* Mar 2008: Fix insmod/rmmod actions. Added new PIO allocate mechanism
* based on platform PIOs dependencies values (LIRC_PIO_ON,
* LIRC_IR_RX, LIRC_UHF_RX so on )
* Angelo Castello <angelo.castello@st.com>
* Apr 2008: Added SCD support
* Angelo Castello <angelo.castello@st.com>
* Carl Shaw <carl.shaw@st.com>
* Feb 2009: Added PM capability
* Angelo Castello <angelo.castello@st.com>
* Francesco Virlinzi <francesco.virlinzi@st.com>
* Jul 2009: ported for kernel 2.6.30 from lirc-0.8.5 project.
* Updated code to manage SCD values incoming from kconfig.
* Default SCD code is for the Futarque RC.
* Angelo Castello <angelo.castello@st.com>
* Apr 2010: Fixed the following SCD issues:
* Q1: to manage rightly border-line symbols
* Q2: to add others constrains for safe initialization.
* Q3: to manage potential contiguous Pulse/Space when the SCD
* programming is not aligned to leading/trailing edge
* Q4: to rebuild rightly the incoming signals train filtered by SCD
* when detected from SCD_CODE or from SCD_ALT_CODE.
* Angelo Castello <angelo.castello@st.com>
* Apr 2010: Code review and optimizations to reduce the driver initialization
* time. All IRB capability are selectable from menuconfig.
* Angelo Castello <angelo.castello@st.com>
* Feb 2011: Fixed IR-RX handler routine to manage the input data overrun.
* Angelo Castello <angelo.castello@st.com>
*/
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/init.h>
#include <linux/uaccess.h>
#include <linux/device.h>
#include <linux/pm_runtime.h>
#include <linux/platform_device.h>
#include <linux/io.h>
#include <linux/irq.h>
#include <linux/ioport.h>
#include <linux/delay.h>
#include <linux/interrupt.h>
#include <linux/gpio.h>
#include <linux/time.h>
#include <linux/lirc.h>
#include <linux/stm/lirc.h>
#include <linux/stm/platform.h>
#include <linux/stm/clk.h>
#include "lirc_dev.h"
#define LIRC_STM_NAME "lirc-stm"
/* General debugging */
#ifdef CONFIG_LIRC_STM_DEBUG
#define DPRINTK(fmt, args...) \
pr_debug(LIRC_STM_NAME ": %s: " fmt, __func__ , ## args)
#else
#define DPRINTK(fmt, args...)
#endif
/*
* LiRC data
*/
static int ir_or_uhf_offset;
static void *irb_base_address; /* IR block register base address */
struct lirc_stm_plugin_data_s {
int open_count;
struct stm_plat_lirc_data *p_lirc_d;
};
static struct lirc_stm_plugin_data_s pd; /* IR data config */
static struct clk *lirc_sys_clock;
/* LIRC subsytem symbol buffer. managed only via common lirc routines
* user process read symbols from here */
struct lirc_buffer lirc_stm_rbuf;
/*
* IRB IR/UHF common configurations
*/
#define IRB_CM_REG(x) (irb_base_address + x)
#define IRB_RX_RATE_COMMON IRB_CM_REG(0x64) /* sample freq divisor*/
#define IRB_RX_CLOCK_SEL IRB_CM_REG(0x70) /* clock select */
#define IRB_RX_CLOCK_SEL_STATUS IRB_CM_REG(0x74) /* clock status */
#define IRB_RX_NOISE_SUPP_WIDTH IRB_CM_REG(0x9C)
#define RX_CLEAR_IRQ(x) writel((x), IRB_RX_INT_CLEAR)
#define RX_WORDS_IN_FIFO_OR_OVERRUN() (readl(IRB_RX_STATUS) & 0xff04)
#define LIRC_STM_MINOR 0
#define LIRC_STM_MAX_SYMBOLS 100
#define LIRC_STM_BUFSIZE (LIRC_STM_MAX_SYMBOLS*sizeof(lirc_t))
/* Bit settings */
#define LIRC_STM_IS_OVERRUN 0x04
#define LIRC_STM_CLEAR_IRQ 0x38
#define LIRC_STM_CLEAR_OVERRUN 0x04
/* IRQ set: Enable full FIFO 1 -> bit 3;
* Enable overrun IRQ 1 -> bit 2;
* Enable last symbol IRQ 1 -> bit 1:
* Enable RX interrupt 1 -> bit 0;
*/
#define LIRC_STM_ENABLE_IRQ 0x0f
/*
* IRB IR/UHF receiver configurations
*/
#define IRB_RX_REG(x) (irb_base_address + x + ir_or_uhf_offset)
#define IRB_RX_ON IRB_RX_REG(0x40) /* pulse time capture */
#define IRB_RX_SYS IRB_RX_REG(0X44) /* sym period capture */
#define IRB_RX_INT_EN IRB_RX_REG(0x48) /* IRQ enable (R/W) */
#define IRB_RX_INT_STATUS IRB_RX_REG(0x4C) /* IRQ status (R/W) */
#define IRB_RX_EN IRB_RX_REG(0x50) /* Receive enablei */
#define IRB_MAX_SYM_PERIOD IRB_RX_REG(0x54) /* max sym value */
#define IRB_RX_INT_CLEAR IRB_RX_REG(0x58) /* overrun status */
#define IRB_RX_STATUS IRB_RX_REG(0x6C) /* receive status */
#define IRB_RX_NOISE_SUPPR IRB_RX_REG(0x5C) /* noise suppression */
#define IRB_RX_POLARITY_INV IRB_RX_REG(0x68) /* polarity inverter */
/* RX graphical example to better understand the difference between ST IR block
* output and standard definition used by LIRC (and most of the world!)
*
* mark mark
* |-IRB_RX_ON-| |-IRB_RX_ON-|
* ___ ___ ___ ___ ___ ___ _
* | | | | | | | | | | | | |
* | | | | | | space 0 | | | | | | space 1 |
* _____| |__| |__| |____________________________| |__| |__| |_____________|
*
* |--------------- IRB_RX_SYS -------------|------ IRB_RX_SYS -------|
*
* |------------- encoding bit 0 -----------|---- encoding bit 1 -----|
*
* ST hardware returns mark (IRB_RX_ON) and total symbol time (IRB_RX_SYS), so
* convert to standard mark/space we have to calculate space=(IRB_RX_SYS - mark)
* The mark time represents the amount of time the carrier (usually 36-40kHz)
* is detected.
*
* TX is the same but with opposite calculation.
*
* The above examples shows Pulse Width Modulation encoding where bit 0 is
* represented by space>mark.
*/
struct lirc_stm_rx_data_s {
/* timing fine control */
int symbol_mult;
int symbol_div;
int pulse_mult;
int pulse_div;
/* data configuration */
unsigned int sampling_freq_div;
lirc_t *rbuf;
unsigned int off_rbuf;
unsigned int sumUs;
int error;
struct timeval sync;
};
static struct lirc_stm_rx_data_s rx; /* RX data config */
/*
* IRB UHF-SCD filter configuration
*/
#ifdef CONFIG_LIRC_STM_UHF_SCD
#define IRB_SCD_CFG IRB_CM_REG(0x200) /* config */
#define IRB_SCD_STA IRB_CM_REG(0x204) /* status */
#define IRB_SCD_CODE IRB_CM_REG(0x208) /* normal code */
#define IRB_SCD_CODE_LEN IRB_CM_REG(0x20c) /* num code symbols */
#define IRB_SCD_SYMB_MIN_TIME IRB_CM_REG(0x210) /* min symbol time */
#define IRB_SCD_SYMB_MAX_TIME IRB_CM_REG(0x214) /* max symbol time */
#define IRB_SCD_SYMB_NOM_TIME IRB_CM_REG(0x218) /* nom symbol time */
#define IRB_SCD_PRESCALAR IRB_CM_REG(0x21c) /* prescalar */
#define IRB_SCD_INT_EN IRB_CM_REG(0x220) /* interrupt enable */
#define IRB_SCD_INT_CLR IRB_CM_REG(0x224) /* interrupt clear */
#define IRB_SCD_INT_STA IRB_CM_REG(0x22c) /* interrupt status */
#define IRB_SCD_NOISE_RECOV IRB_CM_REG(0x228) /* noise recovery */
#define IRB_SCD_ALT_CODE IRB_CM_REG(0x230) /* alternative code */
/* Start Code Detect (SCD) graphical example to understand how to configure
* propely the code, code length and nominal time values based on Remote Control
* signals train example.
*
* __________________ ________ _______ ___ ___ ___
* | | | | | | | | | | | |
* | | | | | | | | | | | |
* _____| |________| |______| |__| |__| |__| |___......
*
* |---- 1000us ----|- 429 -|- 521 -|- 500-|....
* |-- 500 -|- 500 -|- 500 -|- 500 -| units in us for SCD code.
* |-- 1 -|- 1 -|- 0 -|- 1 -| SCD code Ob1101.
*
* The nominal symbol duration is 500us, code length 4 and code Ob1101.
*/
#define LIRC_STM_SCD_MAX_SYMBOLS 32
#define LIRC_STM_SCD_BUFSIZE ((LIRC_STM_SCD_MAX_SYMBOLS/2+1) * \
sizeof(lirc_t))
#define LIRC_STM_SCD_TOLERANCE 25
/* rx.scd_flags fields:
* scd normal 1 -> bit 0
* scd altenative 1 -> bit 1
* scd normal = alternative 1 -> bit 2
* scd enabled 1 -> bit 3
*/
#define SCD_NORMAL 0x01
#define SCD_ALTERNATIVE 0x02
#define SCD_NOR_EQ_ALT 0x04
#define SCD_ENABLED 0x08
#define SCD_ALT_MASK (SCD_NORMAL|SCD_ALTERNATIVE|SCD_ENABLED)
static struct lirc_scd_s scd_s = {
.code = CONFIG_LIRC_STM_UHF_SCD_CODE,
.alt_code = CONFIG_LIRC_STM_UHF_SCD_ALTCODE,
.nomtime = CONFIG_LIRC_STM_UHF_SCD_NTIME,
.noiserecov = 0,
};
/* SCD support */
struct lirc_stm_scd_data_s {
struct lirc_scd_s value;
int flags;
lirc_t *prefix_code;
lirc_t *prefix_altcode;
unsigned int off_prefix_code;
unsigned int off_prefix_altcode;
};
static struct lirc_stm_scd_data_s scd; /* SCD data config */
#endif /* CONFIG_LIRC_STM_UHF_SCD */
/*
* IRB TX transmitter configuration
*/
#ifdef CONFIG_LIRC_STM_TX
#define IRB_TX_REG(x) (irb_base_address + x) /* TX ... */
#define IRB_TX_PRESCALAR IRB_TX_REG(0x00) /* clock prescalar */
#define IRB_TX_SUBCARRIER IRB_TX_REG(0x04) /* subcarrier freq */
#define IRB_TX_SYMPERIOD IRB_TX_REG(0x08) /* symbol period */
#define IRB_TX_ONTIME IRB_TX_REG(0x0c) /* symbol pulse time */
#define IRB_TX_INT_ENABLE IRB_TX_REG(0x10) /* irq enable */
#define IRB_TX_INT_STATUS IRB_TX_REG(0x14) /* irq status */
#define IRB_TX_ENABLE IRB_TX_REG(0x18) /* enable */
#define IRB_TX_INT_CLEAR IRB_TX_REG(0x1c) /* interrupt clear */
#define IRB_TX_SUBCARRIER_WIDTH IRB_TX_REG(0x20) /* subcarrier freq */
#define IRB_TX_STATUS IRB_TX_REG(0x24) /* status */
#define TX_INT_PENDING 0x01
#define TX_INT_UNDERRUN 0x02
#define TX_FIFO_DEPTH 7
#define TX_FIFO_USED ((readl(IRB_TX_STATUS) >> 8) & 0x07)
#define TX_CARRIER_FREQ 38000 /* 38KHz */
struct lirc_stm_tx_data_s {
wait_queue_head_t waitq;
/* timing fine control */
unsigned int mult;
unsigned int div;
/* transmit buffer */
lirc_t *wbuf;
unsigned int off_wbuf;
};
static struct lirc_stm_tx_data_s tx; /* TX data config */
static inline unsigned int lirc_stm_time_to_cycles(unsigned int microsecondtime)
{
/* convert a microsecond time to the nearest number of subcarrier clock
* cycles
*/
microsecondtime *= tx.mult;
microsecondtime /= tx.div;
return microsecondtime * TX_CARRIER_FREQ / 1000000;
}
static ssize_t lirc_stm_write(struct file *file, const char *buf,
size_t n, loff_t *ppos)
{
int i;
size_t rdn = n / sizeof(size_t);
unsigned int symbol, mark;
int fifosyms;
if (!pd.p_lirc_d->txenabled) {
pr_err(LIRC_STM_NAME
": write operation unsupported.\n");
return -ENOTSUPP;
}
if (n % sizeof(lirc_t))
return -EINVAL;
if (tx.off_wbuf != 0 && (file->f_flags & O_NONBLOCK))
return -EAGAIN;
/* Wait for transmit to become free... */
if (wait_event_interruptible(tx.waitq, tx.off_wbuf == 0))
return -ERESTARTSYS;
/* Prevent against buffer overflow... */
if (rdn > LIRC_STM_MAX_SYMBOLS)
rdn = LIRC_STM_MAX_SYMBOLS;
n -= rdn * sizeof(size_t);
if (copy_from_user((char *)tx.wbuf, buf, rdn * sizeof(size_t)))
return -EFAULT;
if (n == 0)
tx.wbuf[rdn - 1] = 0xFFFF;
/* load the first words into the FIFO */
fifosyms = rdn;
if (fifosyms > TX_FIFO_DEPTH)
fifosyms = TX_FIFO_DEPTH;
for (i = 0; i < fifosyms; i++) {
mark = tx.wbuf[(i * 2)];
symbol = mark + tx.wbuf[(i * 2) + 1];
DPRINTK("TX raw m %d s %d ", mark, symbol);
mark = lirc_stm_time_to_cycles(mark) + 1;
symbol = lirc_stm_time_to_cycles(symbol) + 2;
DPRINTK("cal m %d s %d\n", mark, symbol);
tx.off_wbuf++;
writel(mark, IRB_TX_ONTIME);
writel(symbol, IRB_TX_SYMPERIOD);
}
/* enable the transmit */
writel(0x07, IRB_TX_INT_ENABLE);
writel(0x01, IRB_TX_ENABLE);
DPRINTK("TX enabled\n");
return n;
}
static void lirc_stm_tx_calc_clocks(unsigned int clockfreq,
unsigned int subwidthpercent)
{
/* We know the system base clock and the required IR carrier frequency
* We now want a divisor of the system base clock that gives the
* nearest integer multiple of the carrier frequency
*/
const unsigned int clkratio = clockfreq / TX_CARRIER_FREQ;
unsigned int scalar, n;
int delta;
unsigned int diffbest = clockfreq, nbest = 0, scalarbest = 0;
unsigned int nmin = clkratio / 255;
if ((nmin & 0x01) == 1)
nmin++;
for (n = nmin; n < clkratio; n += 2) {
scalar = clkratio / n;
if ((scalar & 0x01) == 0 && scalar != 0) {
delta = clockfreq - (scalar * TX_CARRIER_FREQ * n);
if (delta < 0)
delta *= -1;
if (delta < diffbest) { /* better set of parameters ? */
diffbest = delta;
nbest = n;
scalarbest = scalar;
}
if (delta == 0) /* an exact multiple */
break;
}
}
scalarbest /= 2;
nbest *= 2;
DPRINTK("TX clock scalar = %d\n", scalarbest);
DPRINTK("TX subcarrier scalar = %d\n", nbest);
/* Set the registers now */
writel(scalarbest, IRB_TX_PRESCALAR);
writel(nbest, IRB_TX_SUBCARRIER);
writel(nbest * subwidthpercent / 100, IRB_TX_SUBCARRIER_WIDTH);
/* Now calculate timing to subcarrier cycles factors which compensate
* for any remaining difference between our clock ratios and real times
* in microseconds
*/
if (diffbest == 0) {
/* no adjustment required - our clock is running at the required
* speed */
tx.mult = 1;
tx.div = 1;
} else {
/* adjustment is required */
delta = scalarbest * TX_CARRIER_FREQ * nbest;
tx.mult = delta / (clockfreq / 10000);
if (delta < clockfreq) {/* our clock is running too fast */
DPRINTK("clock running slow at %d\n", delta);
tx.div = tx.mult;
tx.mult = 10000;
} else { /* our clock is running too slow */
DPRINTK("clock running fast at %d\n", delta);
tx.div = 10000;
}
}
DPRINTK("TX fine adjustment mult = %d\n", tx.mult);
DPRINTK("TX fine adjustment div = %d\n", tx.div);
init_waitqueue_head(&tx.waitq);
}
static void lirc_stm_tx_interrupt(int irq, void *dev_id)
{
unsigned int symbol, mark, done = 0;
unsigned int tx_irq_status = readl(IRB_TX_INT_STATUS);
if ((tx_irq_status & TX_INT_PENDING) != TX_INT_PENDING)
return;
while (done == 0) {
if (unlikely((readl(IRB_TX_INT_STATUS) & TX_INT_UNDERRUN) ==
TX_INT_UNDERRUN)) {
/* There has been an underrun - clear flag, switch
* off transmitter and signal possible exit
*/
pr_err(LIRC_STM_NAME ": transmit underrun!\n");
writel(0x02, IRB_TX_INT_CLEAR);
writel(0x00, IRB_TX_INT_ENABLE);
writel(0x00, IRB_TX_ENABLE);
done = 1;
DPRINTK("disabled TX\n");
wake_up_interruptible(&tx.waitq);
} else {
int fifoslots = TX_FIFO_USED;
while (fifoslots < TX_FIFO_DEPTH) {
mark = tx.wbuf[(tx.off_wbuf * 2)];
symbol = mark + tx.wbuf[(tx.off_wbuf * 2) + 1];
DPRINTK("TX raw m %d s %d ", mark, symbol);
mark = lirc_stm_time_to_cycles(mark) + 1;
symbol = lirc_stm_time_to_cycles(symbol) + 2;
DPRINTK("cal m %d s %d\n", mark, symbol);
if ((tx.wbuf[(tx.off_wbuf * 2)] == 0xFFFF) ||
(tx.wbuf[(tx.off_wbuf * 2) + 1] == 0xFFFF))
{
/* Dump out last symbol */
writel(mark * 2, IRB_TX_SYMPERIOD);
writel(mark, IRB_TX_ONTIME);
DPRINTK("TX end m %d s %d\n",
mark, mark * 2);
/* flush transmit fifo */
while (TX_FIFO_USED != 0) {
};
writel(0, IRB_TX_SYMPERIOD);
writel(0, IRB_TX_ONTIME);
/* spin until TX fifo empty */
while (TX_FIFO_USED != 0) {
};
/* disable tx interrupts and
* transmitter */
writel(0x07, IRB_TX_INT_CLEAR);
writel(0x00, IRB_TX_INT_ENABLE);
writel(0x00, IRB_TX_ENABLE);
DPRINTK("TX disabled\n");
tx.off_wbuf = 0;
fifoslots = 999;
done = 1;
} else {
writel(symbol, IRB_TX_SYMPERIOD);
writel(mark, IRB_TX_ONTIME);
DPRINTK("Nm %d s %d\n", mark, symbol);
tx.off_wbuf++;
fifoslots = TX_FIFO_USED;
}
}
}
}
}
#define lirc_stm_tx_kzalloc() { \
tx.wbuf = (lirc_t *) devm_kzalloc(dev, \
LIRC_STM_BUFSIZE, \
GFP_KERNEL); \
if (!tx.wbuf) \
return -ENOMEM; \
}
#else
#define lirc_stm_write NULL
#define lirc_stm_tx_kzalloc()
#define lirc_stm_tx_interrupt(irq, dev_id)
#define lirc_stm_tx_calc_clocks(clockfreq, subwidthpercent)
#endif /* CONFIG_LIRC_STM_TX */
#ifdef CONFIG_LIRC_STM_UHF_SCD
static void lirc_stm_scd_prefix_symbols(void)
{
lirc_t *lscd;
unsigned int *offscd;
if (!scd.flags)
return;
DPRINTK("SCD_STA(0x%x)\n", scd.flags & (SCD_ALTERNATIVE | SCD_NORMAL));
/* Here need to take care the following SCD constrain:
* If there is only one start code to be detected, the registers for
* normal and alternative start codes has been programmed with
* identical values. The low significate bits of scd_flags means:
* 1 : SCD_ENABLED
* 1 : SCD_NOR_EQ_ALT
* 1 : SCD_ALTERNATIVE
* 1 : SCD_NORMAL
* 11xx : normal and alternative are the same due to constrain.
* 1001 : normal detected
* 1011 : alternative detected
*/
if ((scd.flags & SCD_NOR_EQ_ALT) || (scd.flags ^ SCD_ALT_MASK)) {
/* normal code detected */
lscd = scd.prefix_code;
offscd = &scd.off_prefix_code;
} else {
/* alternative code detected */
lscd = scd.prefix_altcode;
offscd = &scd.off_prefix_altcode;
}
/* manage potential contiguous Pulse/Space when the SCD programming
* is not aligned to leading/trailing edge
*/
if ((lscd[*offscd - 1] & PULSE_BIT) == (rx.rbuf[0] & PULSE_BIT)) {
rx.rbuf[0] += (lscd[*offscd - 1] & ~PULSE_BIT);
(*offscd)--;
}
lirc_buffer_write_n(&lirc_stm_rbuf, (unsigned char *)lscd, *offscd);
return;
}
static int lirc_stm_scd_set(char enable)
{
if (!scd.flags)
return -1;
if (enable) {
writel(0x01, IRB_SCD_INT_EN);
writel(0x01, IRB_SCD_INT_CLR);
writel(0x01, IRB_SCD_CFG);
} else {
writel(0x00, IRB_SCD_INT_EN);
writel(0x00, IRB_SCD_CFG);
}
DPRINTK("SCD %s\n", (enable ? "enabled" : "disabled"));
return 0;
}
static int lirc_stm_scd_config(unsigned long clk)
{
unsigned int nrec, ival, scwidth;
unsigned int prescalar, tolerance;
unsigned int space, mark;
int i, j, k;
lirc_t *lscd;
unsigned int *offscd;
unsigned int code, codelen, alt_codelen, curr_codelen;
struct lirc_scd_s last_scd = scd.value;
if (!pd.p_lirc_d->rxuhfmode) {
pr_err(LIRC_STM_NAME
": SCD not available in IR-RX mode. Not armed\n");
return -ENOTSUPP;
}
scd.value = scd_s;
scd.flags = 0;
scd.off_prefix_code = 0;
scd.off_prefix_altcode = 0;
codelen = fls(scd.value.code);
if ((scd.value.code == 0) ||
(codelen > LIRC_STM_SCD_MAX_SYMBOLS) || (codelen < 1)) {
pr_err(LIRC_STM_NAME ": SCD invalid start code. Not armed\n");
scd.value = last_scd;
return -EINVAL;
}
alt_codelen = fls(scd.value.alt_code);
if (alt_codelen > 0) {
if ((scd.value.alt_code == 0) ||
(alt_codelen > LIRC_STM_SCD_MAX_SYMBOLS) ||
(alt_codelen < codelen) ||
(scd.value.code == (scd.value.alt_code >>
(alt_codelen - codelen)))) {
pr_err(LIRC_STM_NAME
": SCD invalid alternative code. Not armed\n");
alt_codelen = 0;
}
}
/* SCD disable */
writel(0x00, IRB_SCD_CFG);
/* Configure pre-scalar clock first to give 1MHz sampling */
prescalar = clk / 1000000;
writel(prescalar, IRB_SCD_PRESCALAR);
/* pre-loading of not filtered SCD codes and
* preparing data for tolerance calculation.
*/
lscd = scd.prefix_code;
offscd = &scd.off_prefix_code;
code = scd.value.code;
curr_codelen = codelen;
for (k = 0; k < 2; k++) {
space = 0;
mark = 0;
j = 0;
for (i = (curr_codelen - 1); i >= 0; i--) {
j = 1 << (i - 1);
if (code & (1 << i)) {
mark += scd.value.nomtime;
if (!(code & j) || (i == 0)) {
lscd[*offscd] = mark | PULSE_BIT;
DPRINTK("SCD mark rscd[%d](%d)\n",
*offscd,
lscd[*offscd] & ~PULSE_BIT);
(*offscd)++;
mark = 0;
}
} else {
space += scd.value.nomtime;
if ((code & j) || (i == 0)) {
lscd[*offscd] = space;
DPRINTK("SCD space rscd[%d](%d)\n",
*offscd, lscd[*offscd]);
(*offscd)++;
space = 0;
}
}
}
lscd = scd.prefix_altcode;
offscd = &scd.off_prefix_altcode;
code = scd.value.alt_code;
curr_codelen = alt_codelen;
}
/* normaly 20% of nomtine is enough as tolerance */
tolerance = scd.value.nomtime * LIRC_STM_SCD_TOLERANCE / 100;
DPRINTK("SCD prescalar %d nominal %d tolerance %d\n",
prescalar, scd.value.nomtime, tolerance);
/* Sanity check to garantee all hw constrains must be satisfied */
if ((tolerance > ((scd.value.nomtime >> 1) - scd.value.nomtime)) ||
(scd.value.nomtime < ((scd.value.nomtime >> 1) + tolerance))) {
tolerance = scd.value.nomtime * LIRC_STM_SCD_TOLERANCE / 100;
DPRINTK("SCD tolerance out of range. default %d\n", tolerance);
}
if (tolerance < 4) {
tolerance = scd.value.nomtime * LIRC_STM_SCD_TOLERANCE / 100;
DPRINTK("SCD tolerance too close. default %d\n", tolerance);
}
/* Program in scd codes and lengths */
writel(scd.value.code, IRB_SCD_CODE);
/* Some cuts of chips have broken SCD, so check... */
i = readl(IRB_SCD_CODE);
if (i != scd.value.code) {
pr_err(LIRC_STM_NAME
": SCD hardware fault. Broken silicon?\n");
pr_err(LIRC_STM_NAME
": SCD wrote code 0x%08x read 0x%08x. Not armed\n",
scd.value.code, i);
scd.value = last_scd;
return -ENODEV;
}
/* Program scd min time, max time and nominal time */
writel(scd.value.nomtime - tolerance, IRB_SCD_SYMB_MIN_TIME);
writel(scd.value.nomtime, IRB_SCD_SYMB_NOM_TIME);
writel(scd.value.nomtime + tolerance, IRB_SCD_SYMB_MAX_TIME);
/* Program in noise recovery (if required) */
if (scd.value.noiserecov) {
nrec = 1 | (1 << 16); /* primary and alt code enable */
i = 1 << (codelen - 1);
ival = scd.value.code & i;
if (ival)
nrec |= 2;
scwidth = 0;
while (i > 0 && ((scd.value.code & i) == ival)) {
scwidth++;
i >>= 1;
}
nrec |= (scwidth << 8);
i = 1 << (alt_codelen - 1);
ival = scd.value.alt_code & i;
if (ival)
nrec |= 1 << 17;
scwidth = 0;
while (i > 0 && ((scd.value.alt_code & i) == ival)) {
scwidth++;
i >>= 1;
}
nrec |= (scwidth << 24);
DPRINTK("SCD noise recovery 0x%08x\n", nrec);
writel(nrec, IRB_SCD_NOISE_RECOV);
}
/* Set supported flag */
pr_info(LIRC_STM_NAME
": SCD normal code 0x%x codelen 0x%x nomtime 0x%x armed\n",
scd.value.code, codelen, scd.value.nomtime);
if (alt_codelen > 0) {
pr_info(LIRC_STM_NAME
": SCD alternative code 0x%x codelen 0x%x armed\n",
scd.value.alt_code, alt_codelen);
writel(scd.value.alt_code, IRB_SCD_ALT_CODE);
} else {
writel(scd.value.code, IRB_SCD_ALT_CODE);
alt_codelen = codelen;
scd.flags |= SCD_NOR_EQ_ALT;
}
/* SCD codelen range [00001,...,11111,00000] where 00000 = 32 symbols */
writel(((alt_codelen & 0x1f) << 8)
| (codelen & 0x1f), IRB_SCD_CODE_LEN);
scd.flags |= SCD_ENABLED;
return 0;
}
#define lirc_stm_scd_kzalloc() { \
scd.prefix_code = (lirc_t *) devm_kzalloc(dev, \
LIRC_STM_SCD_BUFSIZE, \
GFP_KERNEL); \
if (!scd.prefix_code) \
return -ENOMEM; \
\
scd.prefix_altcode = (lirc_t *) devm_kzalloc(dev, \
LIRC_STM_SCD_BUFSIZE, \
GFP_KERNEL); \
if (!scd.prefix_altcode) \
return -ENOMEM; \
}
#define lirc_stm_scd_reactivate() { \
if (scd.flags && lastSymbol) { \
/* reset the SCD flags */ \
scd.flags &= (SCD_ENABLED | SCD_NOR_EQ_ALT); \
writel(0x01, IRB_SCD_INT_EN); \
writel(0x01, IRB_SCD_CFG); \
} \
}
#define lirc_stm_scd_set_flags() { \
if (scd.flags) { \
/* SCD status catched only the first time */ \
if (!(scd.flags & SCD_NORMAL)) { \
scd.flags |= readb(IRB_SCD_STA); \
writel(0x01, IRB_SCD_INT_CLR); \
writel(0x00, IRB_SCD_INT_EN); \
} \
} \
}
#define lirc_stm_scd_cases() { \
case LIRC_SCD_CONFIGURE: \
if (copy_from_user(&scd_s, (unsigned long *)arg,\
sizeof(scd_s))) \
return -EFAULT; \
retval = lirc_stm_scd_config( \
clk_get_rate(lirc_sys_clock)); \
break; \
case LIRC_SCD_ENABLE: \
case LIRC_SCD_DISABLE: \
retval = lirc_stm_scd_set( \
cmd == LIRC_SCD_ENABLE); \
break; \
case LIRC_SCD_STATUS: \
retval = put_user(scd.flags & SCD_ENABLED, \
(unsigned long *)arg); \
break; \
case LIRC_SCD_GET_VALUE: \
if (copy_to_user((unsigned long *)arg, \
&scd.value, \
sizeof(scd_s))) \
return -EFAULT; \
break; \
}
#define lirc_stm_scd_restart() { \
writel(0x02, IRB_SCD_CFG); \
writel(0x01, IRB_SCD_CFG); \
}
#else
#define lirc_stm_scd_prefix_symbols()
#define lirc_stm_scd_set(enable)
#define lirc_stm_scd_config(clk)
#define lirc_stm_scd_reactivate()
#define lirc_stm_scd_set_flags()
#define lirc_stm_scd_restart()
#define lirc_stm_scd_kzalloc()
#define lirc_stm_scd_cases() { \
case LIRC_SCD_CONFIGURE: case LIRC_SCD_ENABLE: \
case LIRC_SCD_DISABLE: case LIRC_SCD_STATUS: \
msg = "LIRC_SCD_xxx"; \
goto _not_supported; \
}
#endif /* CONFIG_LIRC_STM_UHF_SCD */
static inline void lirc_stm_rx_reset_data(void)
{
rx.error = 0;
rx.off_rbuf = 0;
rx.sumUs = 0;
memset(rx.rbuf, 0, LIRC_STM_BUFSIZE);
}
static void lirc_stm_rx_interrupt(int irq, void *dev_id)
{
unsigned int symbol, mark = 0;
int lastSymbol = 0, clear_irq = 1;
lirc_stm_scd_set_flags();
while (RX_WORDS_IN_FIFO_OR_OVERRUN()) {
/* discard the entire collection in case of errors! */
if (unlikely(readl(IRB_RX_INT_STATUS) & LIRC_STM_IS_OVERRUN)) {
pr_info(LIRC_STM_NAME ": IR RX overrun\n");
writel(LIRC_STM_CLEAR_OVERRUN, IRB_RX_INT_CLEAR);
rx.error = 1;
}
/* get the symbol times from FIFO */
symbol = (readl(IRB_RX_SYS));
mark = (readl(IRB_RX_ON));
if (clear_irq) {
/* Clear the interrupt
* and leave only the overrun irq enabled */
RX_CLEAR_IRQ(LIRC_STM_CLEAR_IRQ);
writel(0x07, IRB_RX_INT_EN);
clear_irq = 0;
}
if (rx.off_rbuf >= LIRC_STM_MAX_SYMBOLS) {
pr_info(LIRC_STM_NAME
": IR too many symbols (max %d)\n",
LIRC_STM_MAX_SYMBOLS);
rx.error = 1;
}
/* now handle the data depending on error condition */
if (rx.error) {
/* Try again */
lirc_stm_rx_reset_data();
continue;
}
if (symbol == 0xFFFF)
lastSymbol = 1;
else
lastSymbol = 0;
/* A sequence seems to start with a constant time symbol (1us)
* pulse and symbol time length, both of 1us. We ignore this.
*/
if ((mark > 2) && (symbol > 1)) {
/* Make fine adjustments to timings */
symbol -= mark; /* to get space timing */
symbol *= rx.symbol_mult;
symbol /= rx.symbol_div;
mark *= rx.pulse_mult;
mark /= rx.pulse_div;
/* The ST hardware returns the pulse time and the
* period, which is the pulse time + space time, so
* we need to subtract the pulse time from the period
* to get the space time.
* For a pulse in LIRC MODE2, we need to set the
* PULSE_BIT ON
*/
rx.rbuf[(rx.off_rbuf * 2)] = mark | PULSE_BIT;
rx.rbuf[(rx.off_rbuf * 2) + 1] = symbol;
rx.sumUs += mark + symbol;
rx.off_rbuf++;
if (lastSymbol) {
/* move the entire collection into user
* buffer if enough space, drop otherwise
* (perhaps too crude a recovery?)
* We need to have enough space to move SCD
* symbols yet (max 32).
*/
if (likely(lirc_buffer_available
(&lirc_stm_rbuf) >=
((2 * rx.off_rbuf) + 32))) {
struct timeval now;
lirc_t syncSpace;
DPRINTK("W symbols = %d\n",
rx.off_rbuf);
/* Calculate and write the leading
* space. All spaces and pulses
* together sum up to the
* microseconds elapsed since we
* sent the previous block of data
*/
do_gettimeofday(&now);
if (now.tv_sec - rx.sync.tv_sec < 0)
syncSpace = 0;
else if (now.tv_sec -
rx.sync.tv_sec >
PULSE_MASK / 1000000)
syncSpace = PULSE_MASK;
else {
syncSpace =
(now.tv_sec -
rx.sync.tv_sec) *
1000000 +
(now.tv_usec -
rx.sync.tv_usec);
syncSpace -=
(rx.sumUs -
rx.rbuf[((rx.off_rbuf -
1) * 2) + 1]);
if (syncSpace < 0)
syncSpace = 0;
else if (syncSpace > PULSE_MASK)
syncSpace = PULSE_MASK;
}
_lirc_buffer_write_1
(&lirc_stm_rbuf, (unsigned char *)
&syncSpace);
rx.sync = now;
/* Now write the SCD filtered-out
* pulse / space pairs
*/
lirc_stm_scd_prefix_symbols();
/* Now write the pulse / space pairs
* EXCEPT FOR THE LAST SPACE
* The last space value should be
* 0xFFFF to denote a timeout
*/
lirc_buffer_write_n
(&lirc_stm_rbuf,
(unsigned char *)rx.rbuf,
(2 * rx.off_rbuf) - 1);
wake_up_interruptible
(&lirc_stm_rbuf.wait_poll);
} else
pr_err(LIRC_STM_NAME
": not enough space "
"in user buffer\n");
lirc_stm_rx_reset_data();
}
}
} /* while */
RX_CLEAR_IRQ(LIRC_STM_CLEAR_IRQ | 0x02);
writel(LIRC_STM_ENABLE_IRQ, IRB_RX_INT_EN);
lirc_stm_scd_reactivate();
}
static irqreturn_t lirc_stm_interrupt(int irq, void *dev_id)
{
lirc_stm_tx_interrupt(irq, dev_id);
lirc_stm_rx_interrupt(irq, dev_id);
return IRQ_HANDLED;
}
static int lirc_stm_open_inc(void *data)
{
struct lirc_stm_plugin_data_s *lpd =
(struct lirc_stm_plugin_data_s *)data;
DPRINTK("entering open\n");
if (lpd->open_count++ == 0) {
unsigned long flags;
DPRINTK("plugin enabled\n");
local_irq_save(flags);
/* enable interrupts and receiver */
writel(LIRC_STM_ENABLE_IRQ, IRB_RX_INT_EN);
writel(0x01, IRB_RX_EN);
lirc_stm_rx_reset_data();
local_irq_restore(flags);
lirc_stm_scd_set(1);
} else
DPRINTK("plugin already open\n");
return 0;
}
static void lirc_stm_rx_flush(void)
{
lirc_stm_scd_set(0);
/* Disable receiver */
writel(0x00, IRB_RX_EN);
/* Disable interrupt */
writel(0x20, IRB_RX_INT_EN);
/* clean the buffer */
lirc_stm_rx_reset_data();
}
/*
** Called by lirc_dev as a last action on a real close
*/
static void lirc_stm_close_dec(void *data)
{
struct lirc_stm_plugin_data_s *lpd =
(struct lirc_stm_plugin_data_s *)data;
DPRINTK("entering close\n");
/* The last close disable the receiver */
if (--lpd->open_count == 0)
lirc_stm_rx_flush();
}
static int lirc_stm_ioctl(struct inode *node, struct file *filep,
unsigned int cmd, unsigned long arg)
{
int retval = 0;
unsigned long value = 0;
char *msg = "";
switch (cmd) {
case LIRC_GET_FEATURES:
/*
* Our driver can receive in mode2 and send in pulse mode.
* TODO: We can generate our own carrier freq
* (LIRC_CAN_SET_SEND_CARRIER) and also change duty
* cycle (LIRC_CAN_SET_SEND_DUTY_CYCLE)
*/
DPRINTK("LIRC_GET_FEATURES return REC_MODE2|SEND_PULSE\n");
retval =
put_user(LIRC_CAN_REC_MODE2 | LIRC_CAN_SEND_PULSE,
(unsigned long *)arg);
break;
case LIRC_GET_REC_MODE:
DPRINTK("LIRC_GET_REC_MODE return LIRC_MODE_MODE2\n");
retval = put_user(LIRC_MODE_MODE2, (unsigned long *)arg);
break;
case LIRC_SET_REC_MODE:
retval = get_user(value, (unsigned long *)arg);
DPRINTK("LIRC_SET_REC_MODE to 0x%lx\n", value);
if (value != LIRC_MODE_MODE2)
retval = -ENOSYS;
break;
case LIRC_GET_SEND_MODE:
DPRINTK("LIRC_GET_SEND_MODE return LIRC_MODE_PULSE\n");
retval = put_user(LIRC_MODE_PULSE, (unsigned long *)arg);
break;
case LIRC_SET_SEND_MODE:
retval = get_user(value, (unsigned long *)arg);
DPRINTK("LIRC_SET_SEND_MODE to 0x%lx\n", value);
/* only LIRC_MODE_PULSE supported */
if (value != LIRC_MODE_PULSE)
return (-ENOSYS);
break;
lirc_stm_scd_cases();
case LIRC_GET_REC_RESOLUTION:
msg = "LIRC_GET_REC_RESOLUTION";
goto _not_supported;
case LIRC_GET_REC_CARRIER:
msg = "LIRC_GET_REC_CARRIER";
goto _not_supported;
case LIRC_SET_REC_CARRIER:
msg = "LIRC_SET_REC_CARRIER";
goto _not_supported;
case LIRC_GET_SEND_CARRIER:
msg = "LIRC_GET_SEND_CARRIER";
goto _not_supported;
case LIRC_SET_SEND_CARRIER:
msg = "LIRC_SET_SEND_CARRIER";
goto _not_supported;
case LIRC_GET_REC_DUTY_CYCLE:
msg = "LIRC_GET_REC_DUTY_CYCLE";
goto _not_supported;
case LIRC_SET_REC_DUTY_CYCLE:
msg = "LIRC_SET_REC_DUTY_CYCLE";
goto _not_supported;
case LIRC_GET_SEND_DUTY_CYCLE:
msg = "LIRC_GET_SEND_DUTY_CYCLE";
goto _not_supported;
case LIRC_SET_SEND_DUTY_CYCLE:
msg = "LIRC_SET_SEND_DUTY_CYCLE";
goto _not_supported;
case LIRC_GET_LENGTH:
msg = "LIRC_GET_LENGTH";
goto _not_supported;
default:
msg = "???";
_not_supported:
DPRINTK("command %s (0x%x) not supported\n", msg, cmd);
retval = -ENOIOCTLCMD;
}
return retval;
}
static void
lirc_stm_rx_calc_clocks(struct platform_device *pdev, unsigned long baseclock)
{
struct stm_plat_lirc_data *lirc_pdata = NULL;
unsigned int rx_max_symbol_per;
lirc_pdata = pdev->dev.platform_data;
if (lirc_pdata->irbclkdiv == 0) {
/* Auto-calculate clock divisor */
int freqdiff;
rx.sampling_freq_div = baseclock / 10000000;
/* Work out the timing adjustment factors */
freqdiff = baseclock - (rx.sampling_freq_div * 10000000);
/* freqdiff contains the difference between our clock and a
* true 10 MHz clock which the IR block wants
*/
if (freqdiff == 0) {
/* no adjustment required - our clock is running at the
* required speed
*/
rx.symbol_mult = 1;
rx.pulse_mult = 1;
rx.symbol_div = 1;
rx.pulse_div = 1;
} else {
/* adjustment is required */
rx.symbol_mult =
baseclock / (10000 * rx.sampling_freq_div);
if (freqdiff > 0) {
/* our clock is running too fast */
rx.pulse_mult = 1000;
rx.pulse_div = rx.symbol_mult;
rx.symbol_mult = rx.pulse_mult;
rx.symbol_div = rx.pulse_div;
} else {
/* our clock is running too slow */
rx.symbol_div = 1000;
rx.pulse_mult = rx.symbol_mult;
rx.pulse_div = 1000;
}
}
} else {
rx.sampling_freq_div = (lirc_pdata->irbclkdiv);
rx.symbol_mult = (lirc_pdata->irbperiodmult);
rx.symbol_div = (lirc_pdata->irbperioddiv);
}
writel(rx.sampling_freq_div, IRB_RX_RATE_COMMON);
DPRINTK("IR base clock is %lu\n", baseclock);
DPRINTK("IR clock divisor is %d\n", rx.sampling_freq_div);
DPRINTK("IR clock divisor readlack is %d\n", readl(IRB_RX_RATE_COMMON));
DPRINTK("IR period mult factor is %d\n", rx.symbol_mult);
DPRINTK("IR period divisor factor is %d\n", rx.symbol_div);
DPRINTK("IR pulse mult factor is %d\n", rx.pulse_mult);
DPRINTK("IR pulse divisor factor is %d\n", rx.pulse_div);
/* maximum symbol period.
* Symbol periods longer than this will generate
* an interrupt and terminate a command
*/
if ((lirc_pdata->irbrxmaxperiod) != 0)
rx_max_symbol_per =
(lirc_pdata->irbrxmaxperiod) *
rx.symbol_mult / rx.symbol_div;
else
rx_max_symbol_per = 0;
DPRINTK("RX Maximum symbol period register 0x%x\n", rx_max_symbol_per);
writel(rx_max_symbol_per, IRB_MAX_SYM_PERIOD);
}
static int lirc_stm_hardware_init(struct platform_device *pdev)
{
struct stm_plat_lirc_data *lirc_pdata;
unsigned int scwidth;
int baseclock;
/* set up the hardware version dependent setup parameters */
lirc_pdata = pdev->dev.platform_data;
/* Set the polarity inversion bit to the correct state */
writel(lirc_pdata->rxpolarity, IRB_RX_POLARITY_INV);
/* Get or calculate the clock and timing adjustment values.
* We can auto-calculate these in some cases
*/
baseclock = clk_get_rate(lirc_sys_clock) / lirc_pdata->sysclkdiv;
lirc_stm_rx_calc_clocks(pdev, baseclock);
/* Set up the transmit timings */
if (lirc_pdata->subcarrwidth != 0)
scwidth = lirc_pdata->subcarrwidth;
else
scwidth = 50;
if (scwidth > 100)
scwidth = 50;
DPRINTK("subcarrier width set to %d %%\n", scwidth);
lirc_stm_tx_calc_clocks(baseclock, scwidth);
lirc_stm_scd_config(baseclock);
return 0;
}
static int lirc_stm_remove(struct platform_device *pdev)
{
DPRINTK("lirc_stm_remove called\n");
clk_disable(lirc_sys_clock);
return 0;
}
static int lirc_stm_probe(struct platform_device *pdev)
{
int ret = -EINVAL;
struct device *dev = &pdev->dev;
struct resource *res;
int irb_irq, irb_irq_wup;
irb_irq = irb_irq_wup = 0;
if (pdev->name == NULL) {
pr_err(LIRC_STM_NAME
": probe failed. Check kernel SoC config.\n");
return -ENODEV;
}
lirc_sys_clock = clk_get(NULL, "comms_clk");
if (!lirc_sys_clock) {
pr_err(LIRC_STM_NAME " system clock not found\n");
return -ENODEV;
}
clk_enable(lirc_sys_clock);
pr_info(LIRC_STM_NAME
": probe found data for platform device %s\n", pdev->name);
pd.p_lirc_d = pdev->dev.platform_data;
irb_irq = platform_get_irq(pdev, 0);
if (irb_irq < 0) {
pr_err(LIRC_STM_NAME
": IRQ configuration not found\n");
return -ENODEV;
}
if (devm_request_irq(dev, irb_irq, lirc_stm_interrupt, IRQF_DISABLED,
LIRC_STM_NAME, (void *)&pd) < 0) {
pr_err(LIRC_STM_NAME ": IRQ %d register failed\n", irb_irq);
return -EIO;
}
/* Enable wakeup interrupt if any */
irb_irq_wup = platform_get_irq(pdev, 1);
if (irb_irq_wup >= 0) {
if (devm_request_irq
(dev, irb_irq_wup, lirc_stm_interrupt, IRQF_DISABLED,
LIRC_STM_NAME, (void *)&pd) < 0) {
pr_err(LIRC_STM_NAME
": wakeup IRQ %d register failed\n",
irb_irq_wup);
return -EIO;
}
disable_irq(irb_irq_wup);
enable_irq_wake(irb_irq_wup);
pr_info(LIRC_STM_NAME
": the driver has wakeup IRQ %d\n", irb_irq_wup);
}
/* Configure for ir or uhf. rxuhfmode==1 is UHF */
if (pd.p_lirc_d->rxuhfmode)
ir_or_uhf_offset = 0x40;
else
ir_or_uhf_offset = 0x00;
/* Hardware IR block setup - the PIO ports should already be set up
* in the board-dependent configuration. We need to remap the
* IR registers into kernel space - we do this in one chunk
*/
if ((rx.rbuf = (lirc_t *) devm_kzalloc(dev,
LIRC_STM_BUFSIZE,
GFP_KERNEL)) == NULL)
return -ENOMEM;
lirc_stm_scd_kzalloc();
lirc_stm_tx_kzalloc();
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (!res) {
pr_err(LIRC_STM_NAME ": IO MEM not found\n");
return -ENODEV;
}
if (!devm_request_mem_region(dev, res->start,
res->end - res->start, LIRC_STM_NAME)) {
pr_err(LIRC_STM_NAME ": request_mem_region failed\n");
return -EBUSY;
}
irb_base_address =
devm_ioremap_nocache(dev, res->start, res->end - res->start);
if (irb_base_address == NULL) {
pr_err(LIRC_STM_NAME ": ioremap failed\n");
ret = -ENOMEM;
} else {
DPRINTK("ioremapped register block at 0x%x\n", res->start);
DPRINTK("ioremapped to 0x%x\n", (unsigned int)irb_base_address);
pr_info(LIRC_STM_NAME ": STM LIRC plugin using IRQ %d"
" in %s mode\n", irb_irq,
pd.p_lirc_d->rxuhfmode ? "UHF" : "IR");
if (!devm_stm_pad_claim(dev, pd.p_lirc_d->pads,
LIRC_STM_NAME)) {
pr_err(LIRC_STM_NAME ": Failed to claim "
"pads!\n");
return -EIO;
}
/* enable signal detection */
ret = lirc_stm_hardware_init(pdev);
device_set_wakeup_capable(&pdev->dev, 1);
/* by default the device is on */
pm_runtime_set_active(&pdev->dev);
pm_suspend_ignore_children(&pdev->dev, 1);
pm_runtime_enable(&pdev->dev);
}
return ret;
}
#ifdef CONFIG_PM
static void lirc_stm_rx_restore(void)
{
lirc_stm_scd_set(1);
/* enable interrupts and receiver */
writel(LIRC_STM_ENABLE_IRQ, IRB_RX_INT_EN);
writel(0x01, IRB_RX_EN);
/* clean the buffer */
lirc_stm_rx_reset_data();
}
static int lirc_stm_suspend(struct device *dev)
{
struct platform_device *pdev = to_platform_device(dev);
struct stm_plat_lirc_data *lirc_pdata = NULL;
lirc_pdata = pdev->dev.platform_data;
if (device_may_wakeup(&pdev->dev)) {
/* need for the resuming phase */
lirc_stm_rx_flush();
lirc_stm_rx_calc_clocks(pdev, clk_get_rate(lirc_sys_clock));
lirc_stm_scd_config(clk_get_rate(lirc_sys_clock));
lirc_stm_rx_restore();
lirc_stm_scd_restart();
} else
clk_disable(lirc_sys_clock);
return 0;
}
static int lirc_stm_resume(struct device *dev)
{
struct platform_device *pdev = to_platform_device(dev);
if (!device_may_wakeup(&pdev->dev))
clk_enable(lirc_sys_clock);
lirc_stm_hardware_init(pdev);
lirc_stm_rx_restore();
lirc_stm_scd_restart();
return 0;
}
static int lirc_stm_freeze(struct device *dev)
{
struct platform_device *pdev = to_platform_device(dev);
struct stm_plat_lirc_data *lirc_pdata = NULL;
lirc_pdata = pdev->dev.platform_data;
/* disable IR RX/TX interrupts plus clear status */
writel(0x00, IRB_RX_EN);
writel(0xff, IRB_RX_INT_CLEAR);
/* disabling LIRC irq request */
/* flush LIRC plugin data */
lirc_stm_rx_reset_data();
clk_disable(lirc_sys_clock);
return 0;
}
static int lirc_stm_restore(struct device *dev)
{
struct platform_device *pdev = to_platform_device(dev);
clk_enable(lirc_sys_clock);
lirc_stm_hardware_init(pdev);
/* there was I really open device ? */
if (pd.open_count > 0) {
/* enable interrupts and receiver */
writel(LIRC_STM_ENABLE_IRQ, IRB_RX_INT_EN);
writel(0x01, IRB_RX_EN);
}
return 0;
}
static struct dev_pm_ops stm_lirc_pm_ops = {
.suspend = lirc_stm_suspend, /* on standby/memstandby */
.resume = lirc_stm_resume, /* resume from standby/memstandby */
.freeze = lirc_stm_freeze, /* hibernation */
.restore = lirc_stm_restore, /* resume from hibernation */
.runtime_suspend = lirc_stm_suspend,
.runtime_resume = lirc_stm_resume,
};
#endif
static struct platform_driver lirc_device_driver = {
.driver = {
.name = LIRC_STM_NAME,
.owner = THIS_MODULE,
#ifdef CONFIG_PM
.pm = &stm_lirc_pm_ops,
#endif
},
.probe = lirc_stm_probe,
.remove = lirc_stm_remove,
};
static struct file_operations lirc_stm_fops = {
.write = lirc_stm_write,
.ioctl = lirc_stm_ioctl,
};
static struct lirc_driver lirc_stm_driver = {
.name = LIRC_STM_NAME,
.minor = LIRC_STM_MINOR,
.code_length = 1,
.sample_rate = 0,
/* plugin can receive raw pulse and space timings for each symbol */
.features = LIRC_CAN_REC_MODE2,
/* plugin private data */
.data = (void *)&pd,
/* buffer handled by upper layer */
.add_to_buf = NULL,
#ifndef LIRC_REMOVE_DURING_EXPORT
.get_queue = NULL,
#endif
.set_use_inc = lirc_stm_open_inc,
.set_use_dec = lirc_stm_close_dec,
.fops = &lirc_stm_fops,
.rbuf = &lirc_stm_rbuf,
.owner = THIS_MODULE,
};
static int __init lirc_stm_init(void)
{
DPRINTK("initializing the IR receiver...\n");
if (platform_driver_register(&lirc_device_driver)) {
pr_err(LIRC_STM_NAME
": platform driver register failed\n");
goto out_err;
}
if (!pd.p_lirc_d) {
pr_err(LIRC_STM_NAME
": missed out hardware probing."
"Check kernel SoC config.\n");
goto out_err;
}
/* inform the top level driver that we use our own user buffer */
if (lirc_buffer_init(&lirc_stm_rbuf, sizeof(lirc_t),
(2 * LIRC_STM_MAX_SYMBOLS))) {
pr_err(LIRC_STM_NAME ": buffer init failed\n");
platform_driver_unregister(&lirc_device_driver);
goto out_err;
}
request_module("lirc_dev");
if (lirc_register_driver(&lirc_stm_driver) < 0) {
pr_err(LIRC_STM_NAME ": driver registration failed\n");
lirc_buffer_free(&lirc_stm_rbuf);
platform_driver_unregister(&lirc_device_driver);
goto out_err;
}
pr_info("STMicroelectronics LIRC driver initialized.\n");
return 0;
out_err:
pr_err("STMicroelectronics LIRC driver not initialized.\n");
return -EINVAL;
}
void __exit lirc_stm_release(void)
{
DPRINTK("removing STM lirc driver\n");
/* unregister the driver */
lirc_stm_rx_flush();
platform_driver_unregister(&lirc_device_driver);
/* unplug the lirc stm driver */
if (lirc_unregister_driver(LIRC_STM_MINOR) < 0)
pr_err(LIRC_STM_NAME ": driver unregister failed\n");
/* free buffer */
lirc_buffer_free(&lirc_stm_rbuf);
pr_info("STMicroelectronics LIRC driver removed\n");
}
module_init(lirc_stm_init);
module_exit(lirc_stm_release);
MODULE_DESCRIPTION
("Linux InfraRed receiver driver for STMicroelectronics platforms");
MODULE_AUTHOR("Carl Shaw <carl.shaw@st.com>");
MODULE_AUTHOR("Angelo Castello <angelo.castello@st.com>");
MODULE_LICENSE("GPL");