linux/drivers/media/rc/nuvoton-cir.c
Sean Young 528222d853 media: rc: harmonize infrared durations to microseconds
rc-core kapi uses nanoseconds for infrared durations for receiving, and
microseconds for sending. The uapi already uses microseconds for both,
so this patch does not change the uapi.

Infrared durations do not need nanosecond resolution. IR protocols do not
have durations shorter than about 100 microseconds. Some IR hardware offers
250 microseconds resolution, which is sufficient for most protocols.
Better hardware has 50 microsecond resolution and is enough for every
protocol I am aware off.

Unify on microseconds everywhere. This simplifies the code since less
conversion between microseconds and nanoseconds needs to be done.

This affects:
 - rx_resolution member of struct rc_dev
 - timeout member of struct rc_dev
 - duration member in struct ir_raw_event

Cc: "Bruno Prémont" <bonbons@linux-vserver.org>
Cc: Hans Verkuil <hverkuil-cisco@xs4all.nl>
Cc: Maxim Levitsky <maximlevitsky@gmail.com>
Cc: Patrick Lerda <patrick9876@free.fr>
Cc: Kevin Hilman <khilman@baylibre.com>
Cc: Neil Armstrong <narmstrong@baylibre.com>
Cc: Jerome Brunet <jbrunet@baylibre.com>
Cc: Martin Blumenstingl <martin.blumenstingl@googlemail.com>
Cc: Sean Wang <sean.wang@mediatek.com>
Cc: Matthias Brugger <matthias.bgg@gmail.com>
Cc: Patrice Chotard <patrice.chotard@st.com>
Cc: Maxime Ripard <mripard@kernel.org>
Cc: Chen-Yu Tsai <wens@csie.org>
Cc: "David Härdeman" <david@hardeman.nu>
Cc: Benjamin Valentin <benpicco@googlemail.com>
Cc: Antti Palosaari <crope@iki.fi>
Signed-off-by: Sean Young <sean@mess.org>
Signed-off-by: Mauro Carvalho Chehab <mchehab+huawei@kernel.org>
2020-09-03 16:18:55 +02:00

1121 lines
30 KiB
C

/*
* Driver for Nuvoton Technology Corporation w83667hg/w83677hg-i CIR
*
* Copyright (C) 2010 Jarod Wilson <jarod@redhat.com>
* Copyright (C) 2009 Nuvoton PS Team
*
* Special thanks to Nuvoton for providing hardware, spec sheets and
* sample code upon which portions of this driver are based. Indirect
* thanks also to Maxim Levitsky, whose ene_ir driver this driver is
* modeled after.
*
* 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; either version 2 of the
* License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*/
#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/pnp.h>
#include <linux/io.h>
#include <linux/interrupt.h>
#include <linux/sched.h>
#include <linux/slab.h>
#include <media/rc-core.h>
#include <linux/pci_ids.h>
#include "nuvoton-cir.h"
static void nvt_clear_cir_wake_fifo(struct nvt_dev *nvt);
static const struct nvt_chip nvt_chips[] = {
{ "w83667hg", NVT_W83667HG },
{ "NCT6775F", NVT_6775F },
{ "NCT6776F", NVT_6776F },
{ "NCT6779D", NVT_6779D },
};
static inline struct device *nvt_get_dev(const struct nvt_dev *nvt)
{
return nvt->rdev->dev.parent;
}
static inline bool is_w83667hg(struct nvt_dev *nvt)
{
return nvt->chip_ver == NVT_W83667HG;
}
/* write val to config reg */
static inline void nvt_cr_write(struct nvt_dev *nvt, u8 val, u8 reg)
{
outb(reg, nvt->cr_efir);
outb(val, nvt->cr_efdr);
}
/* read val from config reg */
static inline u8 nvt_cr_read(struct nvt_dev *nvt, u8 reg)
{
outb(reg, nvt->cr_efir);
return inb(nvt->cr_efdr);
}
/* update config register bit without changing other bits */
static inline void nvt_set_reg_bit(struct nvt_dev *nvt, u8 val, u8 reg)
{
u8 tmp = nvt_cr_read(nvt, reg) | val;
nvt_cr_write(nvt, tmp, reg);
}
/* enter extended function mode */
static inline int nvt_efm_enable(struct nvt_dev *nvt)
{
if (!request_muxed_region(nvt->cr_efir, 2, NVT_DRIVER_NAME))
return -EBUSY;
/* Enabling Extended Function Mode explicitly requires writing 2x */
outb(EFER_EFM_ENABLE, nvt->cr_efir);
outb(EFER_EFM_ENABLE, nvt->cr_efir);
return 0;
}
/* exit extended function mode */
static inline void nvt_efm_disable(struct nvt_dev *nvt)
{
outb(EFER_EFM_DISABLE, nvt->cr_efir);
release_region(nvt->cr_efir, 2);
}
/*
* When you want to address a specific logical device, write its logical
* device number to CR_LOGICAL_DEV_SEL, then enable/disable by writing
* 0x1/0x0 respectively to CR_LOGICAL_DEV_EN.
*/
static inline void nvt_select_logical_dev(struct nvt_dev *nvt, u8 ldev)
{
nvt_cr_write(nvt, ldev, CR_LOGICAL_DEV_SEL);
}
/* select and enable logical device with setting EFM mode*/
static inline void nvt_enable_logical_dev(struct nvt_dev *nvt, u8 ldev)
{
nvt_efm_enable(nvt);
nvt_select_logical_dev(nvt, ldev);
nvt_cr_write(nvt, LOGICAL_DEV_ENABLE, CR_LOGICAL_DEV_EN);
nvt_efm_disable(nvt);
}
/* select and disable logical device with setting EFM mode*/
static inline void nvt_disable_logical_dev(struct nvt_dev *nvt, u8 ldev)
{
nvt_efm_enable(nvt);
nvt_select_logical_dev(nvt, ldev);
nvt_cr_write(nvt, LOGICAL_DEV_DISABLE, CR_LOGICAL_DEV_EN);
nvt_efm_disable(nvt);
}
/* write val to cir config register */
static inline void nvt_cir_reg_write(struct nvt_dev *nvt, u8 val, u8 offset)
{
outb(val, nvt->cir_addr + offset);
}
/* read val from cir config register */
static u8 nvt_cir_reg_read(struct nvt_dev *nvt, u8 offset)
{
return inb(nvt->cir_addr + offset);
}
/* write val to cir wake register */
static inline void nvt_cir_wake_reg_write(struct nvt_dev *nvt,
u8 val, u8 offset)
{
outb(val, nvt->cir_wake_addr + offset);
}
/* read val from cir wake config register */
static u8 nvt_cir_wake_reg_read(struct nvt_dev *nvt, u8 offset)
{
return inb(nvt->cir_wake_addr + offset);
}
/* don't override io address if one is set already */
static void nvt_set_ioaddr(struct nvt_dev *nvt, unsigned long *ioaddr)
{
unsigned long old_addr;
old_addr = nvt_cr_read(nvt, CR_CIR_BASE_ADDR_HI) << 8;
old_addr |= nvt_cr_read(nvt, CR_CIR_BASE_ADDR_LO);
if (old_addr)
*ioaddr = old_addr;
else {
nvt_cr_write(nvt, *ioaddr >> 8, CR_CIR_BASE_ADDR_HI);
nvt_cr_write(nvt, *ioaddr & 0xff, CR_CIR_BASE_ADDR_LO);
}
}
static void nvt_write_wakeup_codes(struct rc_dev *dev,
const u8 *wbuf, int count)
{
u8 tolerance, config;
struct nvt_dev *nvt = dev->priv;
unsigned long flags;
int i;
/* hardcode the tolerance to 10% */
tolerance = DIV_ROUND_UP(count, 10);
spin_lock_irqsave(&nvt->lock, flags);
nvt_clear_cir_wake_fifo(nvt);
nvt_cir_wake_reg_write(nvt, count, CIR_WAKE_FIFO_CMP_DEEP);
nvt_cir_wake_reg_write(nvt, tolerance, CIR_WAKE_FIFO_CMP_TOL);
config = nvt_cir_wake_reg_read(nvt, CIR_WAKE_IRCON);
/* enable writes to wake fifo */
nvt_cir_wake_reg_write(nvt, config | CIR_WAKE_IRCON_MODE1,
CIR_WAKE_IRCON);
if (count)
pr_info("Wake samples (%d) =", count);
else
pr_info("Wake sample fifo cleared");
for (i = 0; i < count; i++)
nvt_cir_wake_reg_write(nvt, wbuf[i], CIR_WAKE_WR_FIFO_DATA);
nvt_cir_wake_reg_write(nvt, config, CIR_WAKE_IRCON);
spin_unlock_irqrestore(&nvt->lock, flags);
}
static ssize_t wakeup_data_show(struct device *dev,
struct device_attribute *attr,
char *buf)
{
struct rc_dev *rc_dev = to_rc_dev(dev);
struct nvt_dev *nvt = rc_dev->priv;
int fifo_len, duration;
unsigned long flags;
ssize_t buf_len = 0;
int i;
spin_lock_irqsave(&nvt->lock, flags);
fifo_len = nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFO_COUNT);
fifo_len = min(fifo_len, WAKEUP_MAX_SIZE);
/* go to first element to be read */
while (nvt_cir_wake_reg_read(nvt, CIR_WAKE_RD_FIFO_ONLY_IDX))
nvt_cir_wake_reg_read(nvt, CIR_WAKE_RD_FIFO_ONLY);
for (i = 0; i < fifo_len; i++) {
duration = nvt_cir_wake_reg_read(nvt, CIR_WAKE_RD_FIFO_ONLY);
duration = (duration & BUF_LEN_MASK) * SAMPLE_PERIOD;
buf_len += scnprintf(buf + buf_len, PAGE_SIZE - buf_len,
"%d ", duration);
}
buf_len += scnprintf(buf + buf_len, PAGE_SIZE - buf_len, "\n");
spin_unlock_irqrestore(&nvt->lock, flags);
return buf_len;
}
static ssize_t wakeup_data_store(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t len)
{
struct rc_dev *rc_dev = to_rc_dev(dev);
u8 wake_buf[WAKEUP_MAX_SIZE];
char **argv;
int i, count;
unsigned int val;
ssize_t ret;
argv = argv_split(GFP_KERNEL, buf, &count);
if (!argv)
return -ENOMEM;
if (!count || count > WAKEUP_MAX_SIZE) {
ret = -EINVAL;
goto out;
}
for (i = 0; i < count; i++) {
ret = kstrtouint(argv[i], 10, &val);
if (ret)
goto out;
val = DIV_ROUND_CLOSEST(val, SAMPLE_PERIOD);
if (!val || val > 0x7f) {
ret = -EINVAL;
goto out;
}
wake_buf[i] = val;
/* sequence must start with a pulse */
if (i % 2 == 0)
wake_buf[i] |= BUF_PULSE_BIT;
}
nvt_write_wakeup_codes(rc_dev, wake_buf, count);
ret = len;
out:
argv_free(argv);
return ret;
}
static DEVICE_ATTR_RW(wakeup_data);
/* dump current cir register contents */
static void cir_dump_regs(struct nvt_dev *nvt)
{
nvt_efm_enable(nvt);
nvt_select_logical_dev(nvt, LOGICAL_DEV_CIR);
pr_info("%s: Dump CIR logical device registers:\n", NVT_DRIVER_NAME);
pr_info(" * CR CIR ACTIVE : 0x%x\n",
nvt_cr_read(nvt, CR_LOGICAL_DEV_EN));
pr_info(" * CR CIR BASE ADDR: 0x%x\n",
(nvt_cr_read(nvt, CR_CIR_BASE_ADDR_HI) << 8) |
nvt_cr_read(nvt, CR_CIR_BASE_ADDR_LO));
pr_info(" * CR CIR IRQ NUM: 0x%x\n",
nvt_cr_read(nvt, CR_CIR_IRQ_RSRC));
nvt_efm_disable(nvt);
pr_info("%s: Dump CIR registers:\n", NVT_DRIVER_NAME);
pr_info(" * IRCON: 0x%x\n", nvt_cir_reg_read(nvt, CIR_IRCON));
pr_info(" * IRSTS: 0x%x\n", nvt_cir_reg_read(nvt, CIR_IRSTS));
pr_info(" * IREN: 0x%x\n", nvt_cir_reg_read(nvt, CIR_IREN));
pr_info(" * RXFCONT: 0x%x\n", nvt_cir_reg_read(nvt, CIR_RXFCONT));
pr_info(" * CP: 0x%x\n", nvt_cir_reg_read(nvt, CIR_CP));
pr_info(" * CC: 0x%x\n", nvt_cir_reg_read(nvt, CIR_CC));
pr_info(" * SLCH: 0x%x\n", nvt_cir_reg_read(nvt, CIR_SLCH));
pr_info(" * SLCL: 0x%x\n", nvt_cir_reg_read(nvt, CIR_SLCL));
pr_info(" * FIFOCON: 0x%x\n", nvt_cir_reg_read(nvt, CIR_FIFOCON));
pr_info(" * IRFIFOSTS: 0x%x\n", nvt_cir_reg_read(nvt, CIR_IRFIFOSTS));
pr_info(" * SRXFIFO: 0x%x\n", nvt_cir_reg_read(nvt, CIR_SRXFIFO));
pr_info(" * TXFCONT: 0x%x\n", nvt_cir_reg_read(nvt, CIR_TXFCONT));
pr_info(" * STXFIFO: 0x%x\n", nvt_cir_reg_read(nvt, CIR_STXFIFO));
pr_info(" * FCCH: 0x%x\n", nvt_cir_reg_read(nvt, CIR_FCCH));
pr_info(" * FCCL: 0x%x\n", nvt_cir_reg_read(nvt, CIR_FCCL));
pr_info(" * IRFSM: 0x%x\n", nvt_cir_reg_read(nvt, CIR_IRFSM));
}
/* dump current cir wake register contents */
static void cir_wake_dump_regs(struct nvt_dev *nvt)
{
u8 i, fifo_len;
nvt_efm_enable(nvt);
nvt_select_logical_dev(nvt, LOGICAL_DEV_CIR_WAKE);
pr_info("%s: Dump CIR WAKE logical device registers:\n",
NVT_DRIVER_NAME);
pr_info(" * CR CIR WAKE ACTIVE : 0x%x\n",
nvt_cr_read(nvt, CR_LOGICAL_DEV_EN));
pr_info(" * CR CIR WAKE BASE ADDR: 0x%x\n",
(nvt_cr_read(nvt, CR_CIR_BASE_ADDR_HI) << 8) |
nvt_cr_read(nvt, CR_CIR_BASE_ADDR_LO));
pr_info(" * CR CIR WAKE IRQ NUM: 0x%x\n",
nvt_cr_read(nvt, CR_CIR_IRQ_RSRC));
nvt_efm_disable(nvt);
pr_info("%s: Dump CIR WAKE registers\n", NVT_DRIVER_NAME);
pr_info(" * IRCON: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_IRCON));
pr_info(" * IRSTS: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_IRSTS));
pr_info(" * IREN: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_IREN));
pr_info(" * FIFO CMP DEEP: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFO_CMP_DEEP));
pr_info(" * FIFO CMP TOL: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFO_CMP_TOL));
pr_info(" * FIFO COUNT: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFO_COUNT));
pr_info(" * SLCH: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_SLCH));
pr_info(" * SLCL: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_SLCL));
pr_info(" * FIFOCON: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFOCON));
pr_info(" * SRXFSTS: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_SRXFSTS));
pr_info(" * SAMPLE RX FIFO: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_SAMPLE_RX_FIFO));
pr_info(" * WR FIFO DATA: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_WR_FIFO_DATA));
pr_info(" * RD FIFO ONLY: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_RD_FIFO_ONLY));
pr_info(" * RD FIFO ONLY IDX: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_RD_FIFO_ONLY_IDX));
pr_info(" * FIFO IGNORE: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFO_IGNORE));
pr_info(" * IRFSM: 0x%x\n",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_IRFSM));
fifo_len = nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFO_COUNT);
pr_info("%s: Dump CIR WAKE FIFO (len %d)\n", NVT_DRIVER_NAME, fifo_len);
pr_info("* Contents =");
for (i = 0; i < fifo_len; i++)
pr_cont(" %02x",
nvt_cir_wake_reg_read(nvt, CIR_WAKE_RD_FIFO_ONLY));
pr_cont("\n");
}
static inline const char *nvt_find_chip(struct nvt_dev *nvt, int id)
{
int i;
for (i = 0; i < ARRAY_SIZE(nvt_chips); i++)
if ((id & SIO_ID_MASK) == nvt_chips[i].chip_ver) {
nvt->chip_ver = nvt_chips[i].chip_ver;
return nvt_chips[i].name;
}
return NULL;
}
/* detect hardware features */
static int nvt_hw_detect(struct nvt_dev *nvt)
{
struct device *dev = nvt_get_dev(nvt);
const char *chip_name;
int chip_id;
nvt_efm_enable(nvt);
/* Check if we're wired for the alternate EFER setup */
nvt->chip_major = nvt_cr_read(nvt, CR_CHIP_ID_HI);
if (nvt->chip_major == 0xff) {
nvt_efm_disable(nvt);
nvt->cr_efir = CR_EFIR2;
nvt->cr_efdr = CR_EFDR2;
nvt_efm_enable(nvt);
nvt->chip_major = nvt_cr_read(nvt, CR_CHIP_ID_HI);
}
nvt->chip_minor = nvt_cr_read(nvt, CR_CHIP_ID_LO);
nvt_efm_disable(nvt);
chip_id = nvt->chip_major << 8 | nvt->chip_minor;
if (chip_id == NVT_INVALID) {
dev_err(dev, "No device found on either EFM port\n");
return -ENODEV;
}
chip_name = nvt_find_chip(nvt, chip_id);
/* warn, but still let the driver load, if we don't know this chip */
if (!chip_name)
dev_warn(dev,
"unknown chip, id: 0x%02x 0x%02x, it may not work...",
nvt->chip_major, nvt->chip_minor);
else
dev_info(dev, "found %s or compatible: chip id: 0x%02x 0x%02x",
chip_name, nvt->chip_major, nvt->chip_minor);
return 0;
}
static void nvt_cir_ldev_init(struct nvt_dev *nvt)
{
u8 val, psreg, psmask, psval;
if (is_w83667hg(nvt)) {
psreg = CR_MULTIFUNC_PIN_SEL;
psmask = MULTIFUNC_PIN_SEL_MASK;
psval = MULTIFUNC_ENABLE_CIR | MULTIFUNC_ENABLE_CIRWB;
} else {
psreg = CR_OUTPUT_PIN_SEL;
psmask = OUTPUT_PIN_SEL_MASK;
psval = OUTPUT_ENABLE_CIR | OUTPUT_ENABLE_CIRWB;
}
/* output pin selection: enable CIR, with WB sensor enabled */
val = nvt_cr_read(nvt, psreg);
val &= psmask;
val |= psval;
nvt_cr_write(nvt, val, psreg);
/* Select CIR logical device */
nvt_select_logical_dev(nvt, LOGICAL_DEV_CIR);
nvt_set_ioaddr(nvt, &nvt->cir_addr);
nvt_cr_write(nvt, nvt->cir_irq, CR_CIR_IRQ_RSRC);
nvt_dbg("CIR initialized, base io port address: 0x%lx, irq: %d",
nvt->cir_addr, nvt->cir_irq);
}
static void nvt_cir_wake_ldev_init(struct nvt_dev *nvt)
{
/* Select ACPI logical device and anable it */
nvt_select_logical_dev(nvt, LOGICAL_DEV_ACPI);
nvt_cr_write(nvt, LOGICAL_DEV_ENABLE, CR_LOGICAL_DEV_EN);
/* Enable CIR Wake via PSOUT# (Pin60) */
nvt_set_reg_bit(nvt, CIR_WAKE_ENABLE_BIT, CR_ACPI_CIR_WAKE);
/* enable pme interrupt of cir wakeup event */
nvt_set_reg_bit(nvt, PME_INTR_CIR_PASS_BIT, CR_ACPI_IRQ_EVENTS2);
/* Select CIR Wake logical device */
nvt_select_logical_dev(nvt, LOGICAL_DEV_CIR_WAKE);
nvt_set_ioaddr(nvt, &nvt->cir_wake_addr);
nvt_dbg("CIR Wake initialized, base io port address: 0x%lx",
nvt->cir_wake_addr);
}
/* clear out the hardware's cir rx fifo */
static void nvt_clear_cir_fifo(struct nvt_dev *nvt)
{
u8 val = nvt_cir_reg_read(nvt, CIR_FIFOCON);
nvt_cir_reg_write(nvt, val | CIR_FIFOCON_RXFIFOCLR, CIR_FIFOCON);
}
/* clear out the hardware's cir wake rx fifo */
static void nvt_clear_cir_wake_fifo(struct nvt_dev *nvt)
{
u8 val, config;
config = nvt_cir_wake_reg_read(nvt, CIR_WAKE_IRCON);
/* clearing wake fifo works in learning mode only */
nvt_cir_wake_reg_write(nvt, config & ~CIR_WAKE_IRCON_MODE0,
CIR_WAKE_IRCON);
val = nvt_cir_wake_reg_read(nvt, CIR_WAKE_FIFOCON);
nvt_cir_wake_reg_write(nvt, val | CIR_WAKE_FIFOCON_RXFIFOCLR,
CIR_WAKE_FIFOCON);
nvt_cir_wake_reg_write(nvt, config, CIR_WAKE_IRCON);
}
/* clear out the hardware's cir tx fifo */
static void nvt_clear_tx_fifo(struct nvt_dev *nvt)
{
u8 val;
val = nvt_cir_reg_read(nvt, CIR_FIFOCON);
nvt_cir_reg_write(nvt, val | CIR_FIFOCON_TXFIFOCLR, CIR_FIFOCON);
}
/* enable RX Trigger Level Reach and Packet End interrupts */
static void nvt_set_cir_iren(struct nvt_dev *nvt)
{
u8 iren;
iren = CIR_IREN_RTR | CIR_IREN_PE | CIR_IREN_RFO;
nvt_cir_reg_write(nvt, iren, CIR_IREN);
}
static void nvt_cir_regs_init(struct nvt_dev *nvt)
{
nvt_enable_logical_dev(nvt, LOGICAL_DEV_CIR);
/* set sample limit count (PE interrupt raised when reached) */
nvt_cir_reg_write(nvt, CIR_RX_LIMIT_COUNT >> 8, CIR_SLCH);
nvt_cir_reg_write(nvt, CIR_RX_LIMIT_COUNT & 0xff, CIR_SLCL);
/* set fifo irq trigger levels */
nvt_cir_reg_write(nvt, CIR_FIFOCON_TX_TRIGGER_LEV |
CIR_FIFOCON_RX_TRIGGER_LEV, CIR_FIFOCON);
/* clear hardware rx and tx fifos */
nvt_clear_cir_fifo(nvt);
nvt_clear_tx_fifo(nvt);
nvt_disable_logical_dev(nvt, LOGICAL_DEV_CIR);
}
static void nvt_cir_wake_regs_init(struct nvt_dev *nvt)
{
nvt_enable_logical_dev(nvt, LOGICAL_DEV_CIR_WAKE);
/*
* Disable RX, set specific carrier on = low, off = high,
* and sample period (currently 50us)
*/
nvt_cir_wake_reg_write(nvt, CIR_WAKE_IRCON_MODE0 |
CIR_WAKE_IRCON_R | CIR_WAKE_IRCON_RXINV |
CIR_WAKE_IRCON_SAMPLE_PERIOD_SEL,
CIR_WAKE_IRCON);
/* clear any and all stray interrupts */
nvt_cir_wake_reg_write(nvt, 0xff, CIR_WAKE_IRSTS);
}
static void nvt_enable_wake(struct nvt_dev *nvt)
{
unsigned long flags;
nvt_efm_enable(nvt);
nvt_select_logical_dev(nvt, LOGICAL_DEV_ACPI);
nvt_set_reg_bit(nvt, CIR_WAKE_ENABLE_BIT, CR_ACPI_CIR_WAKE);
nvt_set_reg_bit(nvt, PME_INTR_CIR_PASS_BIT, CR_ACPI_IRQ_EVENTS2);
nvt_select_logical_dev(nvt, LOGICAL_DEV_CIR_WAKE);
nvt_cr_write(nvt, LOGICAL_DEV_ENABLE, CR_LOGICAL_DEV_EN);
nvt_efm_disable(nvt);
spin_lock_irqsave(&nvt->lock, flags);
nvt_cir_wake_reg_write(nvt, CIR_WAKE_IRCON_MODE0 | CIR_WAKE_IRCON_RXEN |
CIR_WAKE_IRCON_R | CIR_WAKE_IRCON_RXINV |
CIR_WAKE_IRCON_SAMPLE_PERIOD_SEL,
CIR_WAKE_IRCON);
nvt_cir_wake_reg_write(nvt, 0xff, CIR_WAKE_IRSTS);
nvt_cir_wake_reg_write(nvt, 0, CIR_WAKE_IREN);
spin_unlock_irqrestore(&nvt->lock, flags);
}
#if 0 /* Currently unused */
/* rx carrier detect only works in learning mode, must be called w/lock */
static u32 nvt_rx_carrier_detect(struct nvt_dev *nvt)
{
u32 count, carrier, duration = 0;
int i;
count = nvt_cir_reg_read(nvt, CIR_FCCL) |
nvt_cir_reg_read(nvt, CIR_FCCH) << 8;
for (i = 0; i < nvt->pkts; i++) {
if (nvt->buf[i] & BUF_PULSE_BIT)
duration += nvt->buf[i] & BUF_LEN_MASK;
}
duration *= SAMPLE_PERIOD;
if (!count || !duration) {
dev_notice(nvt_get_dev(nvt),
"Unable to determine carrier! (c:%u, d:%u)",
count, duration);
return 0;
}
carrier = MS_TO_NS(count) / duration;
if ((carrier > MAX_CARRIER) || (carrier < MIN_CARRIER))
nvt_dbg("WTF? Carrier frequency out of range!");
nvt_dbg("Carrier frequency: %u (count %u, duration %u)",
carrier, count, duration);
return carrier;
}
#endif
static int nvt_ir_raw_set_wakeup_filter(struct rc_dev *dev,
struct rc_scancode_filter *sc_filter)
{
u8 buf_val;
int i, ret, count;
unsigned int val;
struct ir_raw_event *raw;
u8 wake_buf[WAKEUP_MAX_SIZE];
bool complete;
/* Require mask to be set */
if (!sc_filter->mask)
return 0;
raw = kmalloc_array(WAKEUP_MAX_SIZE, sizeof(*raw), GFP_KERNEL);
if (!raw)
return -ENOMEM;
ret = ir_raw_encode_scancode(dev->wakeup_protocol, sc_filter->data,
raw, WAKEUP_MAX_SIZE);
complete = (ret != -ENOBUFS);
if (!complete)
ret = WAKEUP_MAX_SIZE;
else if (ret < 0)
goto out_raw;
/* Inspect the ir samples */
for (i = 0, count = 0; i < ret && count < WAKEUP_MAX_SIZE; ++i) {
val = raw[i].duration / SAMPLE_PERIOD;
/* Split too large values into several smaller ones */
while (val > 0 && count < WAKEUP_MAX_SIZE) {
/* Skip last value for better comparison tolerance */
if (complete && i == ret - 1 && val < BUF_LEN_MASK)
break;
/* Clamp values to BUF_LEN_MASK at most */
buf_val = (val > BUF_LEN_MASK) ? BUF_LEN_MASK : val;
wake_buf[count] = buf_val;
val -= buf_val;
if ((raw[i]).pulse)
wake_buf[count] |= BUF_PULSE_BIT;
count++;
}
}
nvt_write_wakeup_codes(dev, wake_buf, count);
ret = 0;
out_raw:
kfree(raw);
return ret;
}
/* dump contents of the last rx buffer we got from the hw rx fifo */
static void nvt_dump_rx_buf(struct nvt_dev *nvt)
{
int i;
printk(KERN_DEBUG "%s (len %d): ", __func__, nvt->pkts);
for (i = 0; (i < nvt->pkts) && (i < RX_BUF_LEN); i++)
printk(KERN_CONT "0x%02x ", nvt->buf[i]);
printk(KERN_CONT "\n");
}
/*
* Process raw data in rx driver buffer, store it in raw IR event kfifo,
* trigger decode when appropriate.
*
* We get IR data samples one byte at a time. If the msb is set, its a pulse,
* otherwise its a space. The lower 7 bits are the count of SAMPLE_PERIOD
* (default 50us) intervals for that pulse/space. A discrete signal is
* followed by a series of 0x7f packets, then either 0x7<something> or 0x80
* to signal more IR coming (repeats) or end of IR, respectively. We store
* sample data in the raw event kfifo until we see 0x7<something> (except f)
* or 0x80, at which time, we trigger a decode operation.
*/
static void nvt_process_rx_ir_data(struct nvt_dev *nvt)
{
struct ir_raw_event rawir = {};
u8 sample;
int i;
nvt_dbg_verbose("%s firing", __func__);
if (debug)
nvt_dump_rx_buf(nvt);
nvt_dbg_verbose("Processing buffer of len %d", nvt->pkts);
for (i = 0; i < nvt->pkts; i++) {
sample = nvt->buf[i];
rawir.pulse = ((sample & BUF_PULSE_BIT) != 0);
rawir.duration = (sample & BUF_LEN_MASK) * SAMPLE_PERIOD;
nvt_dbg("Storing %s with duration %d",
rawir.pulse ? "pulse" : "space", rawir.duration);
ir_raw_event_store_with_filter(nvt->rdev, &rawir);
}
nvt->pkts = 0;
nvt_dbg("Calling ir_raw_event_handle\n");
ir_raw_event_handle(nvt->rdev);
nvt_dbg_verbose("%s done", __func__);
}
static void nvt_handle_rx_fifo_overrun(struct nvt_dev *nvt)
{
dev_warn(nvt_get_dev(nvt), "RX FIFO overrun detected, flushing data!");
nvt->pkts = 0;
nvt_clear_cir_fifo(nvt);
ir_raw_event_reset(nvt->rdev);
}
/* copy data from hardware rx fifo into driver buffer */
static void nvt_get_rx_ir_data(struct nvt_dev *nvt)
{
u8 fifocount;
int i;
/* Get count of how many bytes to read from RX FIFO */
fifocount = nvt_cir_reg_read(nvt, CIR_RXFCONT);
nvt_dbg("attempting to fetch %u bytes from hw rx fifo", fifocount);
/* Read fifocount bytes from CIR Sample RX FIFO register */
for (i = 0; i < fifocount; i++)
nvt->buf[i] = nvt_cir_reg_read(nvt, CIR_SRXFIFO);
nvt->pkts = fifocount;
nvt_dbg("%s: pkts now %d", __func__, nvt->pkts);
nvt_process_rx_ir_data(nvt);
}
static void nvt_cir_log_irqs(u8 status, u8 iren)
{
nvt_dbg("IRQ 0x%02x (IREN 0x%02x) :%s%s%s%s%s%s%s%s%s",
status, iren,
status & CIR_IRSTS_RDR ? " RDR" : "",
status & CIR_IRSTS_RTR ? " RTR" : "",
status & CIR_IRSTS_PE ? " PE" : "",
status & CIR_IRSTS_RFO ? " RFO" : "",
status & CIR_IRSTS_TE ? " TE" : "",
status & CIR_IRSTS_TTR ? " TTR" : "",
status & CIR_IRSTS_TFU ? " TFU" : "",
status & CIR_IRSTS_GH ? " GH" : "",
status & ~(CIR_IRSTS_RDR | CIR_IRSTS_RTR | CIR_IRSTS_PE |
CIR_IRSTS_RFO | CIR_IRSTS_TE | CIR_IRSTS_TTR |
CIR_IRSTS_TFU | CIR_IRSTS_GH) ? " ?" : "");
}
/* interrupt service routine for incoming and outgoing CIR data */
static irqreturn_t nvt_cir_isr(int irq, void *data)
{
struct nvt_dev *nvt = data;
u8 status, iren;
nvt_dbg_verbose("%s firing", __func__);
spin_lock(&nvt->lock);
/*
* Get IR Status register contents. Write 1 to ack/clear
*
* bit: reg name - description
* 7: CIR_IRSTS_RDR - RX Data Ready
* 6: CIR_IRSTS_RTR - RX FIFO Trigger Level Reach
* 5: CIR_IRSTS_PE - Packet End
* 4: CIR_IRSTS_RFO - RX FIFO Overrun (RDR will also be set)
* 3: CIR_IRSTS_TE - TX FIFO Empty
* 2: CIR_IRSTS_TTR - TX FIFO Trigger Level Reach
* 1: CIR_IRSTS_TFU - TX FIFO Underrun
* 0: CIR_IRSTS_GH - Min Length Detected
*/
status = nvt_cir_reg_read(nvt, CIR_IRSTS);
iren = nvt_cir_reg_read(nvt, CIR_IREN);
/* At least NCT6779D creates a spurious interrupt when the
* logical device is being disabled.
*/
if (status == 0xff && iren == 0xff) {
spin_unlock(&nvt->lock);
nvt_dbg_verbose("Spurious interrupt detected");
return IRQ_HANDLED;
}
/* IRQ may be shared with CIR WAKE, therefore check for each
* status bit whether the related interrupt source is enabled
*/
if (!(status & iren)) {
spin_unlock(&nvt->lock);
nvt_dbg_verbose("%s exiting, IRSTS 0x0", __func__);
return IRQ_NONE;
}
/* ack/clear all irq flags we've got */
nvt_cir_reg_write(nvt, status, CIR_IRSTS);
nvt_cir_reg_write(nvt, 0, CIR_IRSTS);
nvt_cir_log_irqs(status, iren);
if (status & CIR_IRSTS_RFO)
nvt_handle_rx_fifo_overrun(nvt);
else if (status & (CIR_IRSTS_RTR | CIR_IRSTS_PE))
nvt_get_rx_ir_data(nvt);
spin_unlock(&nvt->lock);
nvt_dbg_verbose("%s done", __func__);
return IRQ_HANDLED;
}
static void nvt_enable_cir(struct nvt_dev *nvt)
{
unsigned long flags;
/* enable the CIR logical device */
nvt_enable_logical_dev(nvt, LOGICAL_DEV_CIR);
spin_lock_irqsave(&nvt->lock, flags);
/*
* Enable TX and RX, specify carrier on = low, off = high, and set
* sample period (currently 50us)
*/
nvt_cir_reg_write(nvt, CIR_IRCON_TXEN | CIR_IRCON_RXEN |
CIR_IRCON_RXINV | CIR_IRCON_SAMPLE_PERIOD_SEL,
CIR_IRCON);
/* clear all pending interrupts */
nvt_cir_reg_write(nvt, 0xff, CIR_IRSTS);
/* enable interrupts */
nvt_set_cir_iren(nvt);
spin_unlock_irqrestore(&nvt->lock, flags);
}
static void nvt_disable_cir(struct nvt_dev *nvt)
{
unsigned long flags;
spin_lock_irqsave(&nvt->lock, flags);
/* disable CIR interrupts */
nvt_cir_reg_write(nvt, 0, CIR_IREN);
/* clear any and all pending interrupts */
nvt_cir_reg_write(nvt, 0xff, CIR_IRSTS);
/* clear all function enable flags */
nvt_cir_reg_write(nvt, 0, CIR_IRCON);
/* clear hardware rx and tx fifos */
nvt_clear_cir_fifo(nvt);
nvt_clear_tx_fifo(nvt);
spin_unlock_irqrestore(&nvt->lock, flags);
/* disable the CIR logical device */
nvt_disable_logical_dev(nvt, LOGICAL_DEV_CIR);
}
static int nvt_open(struct rc_dev *dev)
{
struct nvt_dev *nvt = dev->priv;
nvt_enable_cir(nvt);
return 0;
}
static void nvt_close(struct rc_dev *dev)
{
struct nvt_dev *nvt = dev->priv;
nvt_disable_cir(nvt);
}
/* Allocate memory, probe hardware, and initialize everything */
static int nvt_probe(struct pnp_dev *pdev, const struct pnp_device_id *dev_id)
{
struct nvt_dev *nvt;
struct rc_dev *rdev;
int ret;
nvt = devm_kzalloc(&pdev->dev, sizeof(struct nvt_dev), GFP_KERNEL);
if (!nvt)
return -ENOMEM;
/* input device for IR remote */
nvt->rdev = devm_rc_allocate_device(&pdev->dev, RC_DRIVER_IR_RAW);
if (!nvt->rdev)
return -ENOMEM;
rdev = nvt->rdev;
/* activate pnp device */
ret = pnp_activate_dev(pdev);
if (ret) {
dev_err(&pdev->dev, "Could not activate PNP device!\n");
return ret;
}
/* validate pnp resources */
if (!pnp_port_valid(pdev, 0) ||
pnp_port_len(pdev, 0) < CIR_IOREG_LENGTH) {
dev_err(&pdev->dev, "IR PNP Port not valid!\n");
return -EINVAL;
}
if (!pnp_irq_valid(pdev, 0)) {
dev_err(&pdev->dev, "PNP IRQ not valid!\n");
return -EINVAL;
}
if (!pnp_port_valid(pdev, 1) ||
pnp_port_len(pdev, 1) < CIR_IOREG_LENGTH) {
dev_err(&pdev->dev, "Wake PNP Port not valid!\n");
return -EINVAL;
}
nvt->cir_addr = pnp_port_start(pdev, 0);
nvt->cir_irq = pnp_irq(pdev, 0);
nvt->cir_wake_addr = pnp_port_start(pdev, 1);
nvt->cr_efir = CR_EFIR;
nvt->cr_efdr = CR_EFDR;
spin_lock_init(&nvt->lock);
pnp_set_drvdata(pdev, nvt);
ret = nvt_hw_detect(nvt);
if (ret)
return ret;
/* Initialize CIR & CIR Wake Logical Devices */
nvt_efm_enable(nvt);
nvt_cir_ldev_init(nvt);
nvt_cir_wake_ldev_init(nvt);
nvt_efm_disable(nvt);
/*
* Initialize CIR & CIR Wake Config Registers
* and enable logical devices
*/
nvt_cir_regs_init(nvt);
nvt_cir_wake_regs_init(nvt);
/* Set up the rc device */
rdev->priv = nvt;
rdev->allowed_protocols = RC_PROTO_BIT_ALL_IR_DECODER;
rdev->allowed_wakeup_protocols = RC_PROTO_BIT_ALL_IR_ENCODER;
rdev->encode_wakeup = true;
rdev->open = nvt_open;
rdev->close = nvt_close;
rdev->s_wakeup_filter = nvt_ir_raw_set_wakeup_filter;
rdev->device_name = "Nuvoton w836x7hg Infrared Remote Transceiver";
rdev->input_phys = "nuvoton/cir0";
rdev->input_id.bustype = BUS_HOST;
rdev->input_id.vendor = PCI_VENDOR_ID_WINBOND2;
rdev->input_id.product = nvt->chip_major;
rdev->input_id.version = nvt->chip_minor;
rdev->driver_name = NVT_DRIVER_NAME;
rdev->map_name = RC_MAP_RC6_MCE;
rdev->timeout = MS_TO_US(100);
/* rx resolution is hardwired to 50us atm, 1, 25, 100 also possible */
rdev->rx_resolution = CIR_SAMPLE_PERIOD;
#if 0
rdev->min_timeout = XYZ;
rdev->max_timeout = XYZ;
#endif
ret = devm_rc_register_device(&pdev->dev, rdev);
if (ret)
return ret;
/* now claim resources */
if (!devm_request_region(&pdev->dev, nvt->cir_addr,
CIR_IOREG_LENGTH, NVT_DRIVER_NAME))
return -EBUSY;
ret = devm_request_irq(&pdev->dev, nvt->cir_irq, nvt_cir_isr,
IRQF_SHARED, NVT_DRIVER_NAME, nvt);
if (ret)
return ret;
if (!devm_request_region(&pdev->dev, nvt->cir_wake_addr,
CIR_IOREG_LENGTH, NVT_DRIVER_NAME "-wake"))
return -EBUSY;
ret = device_create_file(&rdev->dev, &dev_attr_wakeup_data);
if (ret)
return ret;
device_init_wakeup(&pdev->dev, true);
dev_notice(&pdev->dev, "driver has been successfully loaded\n");
if (debug) {
cir_dump_regs(nvt);
cir_wake_dump_regs(nvt);
}
return 0;
}
static void nvt_remove(struct pnp_dev *pdev)
{
struct nvt_dev *nvt = pnp_get_drvdata(pdev);
device_remove_file(&nvt->rdev->dev, &dev_attr_wakeup_data);
nvt_disable_cir(nvt);
/* enable CIR Wake (for IR power-on) */
nvt_enable_wake(nvt);
}
static int nvt_suspend(struct pnp_dev *pdev, pm_message_t state)
{
struct nvt_dev *nvt = pnp_get_drvdata(pdev);
nvt_dbg("%s called", __func__);
mutex_lock(&nvt->rdev->lock);
if (nvt->rdev->users)
nvt_disable_cir(nvt);
mutex_unlock(&nvt->rdev->lock);
/* make sure wake is enabled */
nvt_enable_wake(nvt);
return 0;
}
static int nvt_resume(struct pnp_dev *pdev)
{
struct nvt_dev *nvt = pnp_get_drvdata(pdev);
nvt_dbg("%s called", __func__);
nvt_cir_regs_init(nvt);
nvt_cir_wake_regs_init(nvt);
mutex_lock(&nvt->rdev->lock);
if (nvt->rdev->users)
nvt_enable_cir(nvt);
mutex_unlock(&nvt->rdev->lock);
return 0;
}
static void nvt_shutdown(struct pnp_dev *pdev)
{
struct nvt_dev *nvt = pnp_get_drvdata(pdev);
nvt_enable_wake(nvt);
}
static const struct pnp_device_id nvt_ids[] = {
{ "WEC0530", 0 }, /* CIR */
{ "NTN0530", 0 }, /* CIR for new chip's pnp id*/
{ "", 0 },
};
static struct pnp_driver nvt_driver = {
.name = NVT_DRIVER_NAME,
.id_table = nvt_ids,
.flags = PNP_DRIVER_RES_DO_NOT_CHANGE,
.probe = nvt_probe,
.remove = nvt_remove,
.suspend = nvt_suspend,
.resume = nvt_resume,
.shutdown = nvt_shutdown,
};
module_param(debug, int, S_IRUGO | S_IWUSR);
MODULE_PARM_DESC(debug, "Enable debugging output");
MODULE_DEVICE_TABLE(pnp, nvt_ids);
MODULE_DESCRIPTION("Nuvoton W83667HG-A & W83677HG-I CIR driver");
MODULE_AUTHOR("Jarod Wilson <jarod@redhat.com>");
MODULE_LICENSE("GPL");
module_pnp_driver(nvt_driver);