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kernel / pub / scm / linux / kernel / git / geert / renesas-drivers / e9ebc2151f88600e726e51e5f7ca9c33ad53b35f / . / drivers / auxdisplay / panel.c
blob: 21b9b2f2470a26d1f2d1c2d5eb4237fe3902af82 [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0+
/*
* Front panel driver for Linux
* Copyright (C) 2000-2008, Willy Tarreau <w@1wt.eu>
* Copyright (C) 2016-2017 Glider bvba
*
* This code drives an LCD module (/dev/lcd), and a keypad (/dev/keypad)
* connected to a parallel printer port.
*
* The LCD module may either be an HD44780-like 8-bit parallel LCD, or a 1-bit
* serial module compatible with Samsung's KS0074. The pins may be connected in
* any combination, everything is programmable.
*
* The keypad consists in a matrix of push buttons connecting input pins to
* data output pins or to the ground. The combinations have to be hard-coded
* in the driver, though several profiles exist and adding new ones is easy.
*
* Several profiles are provided for commonly found LCD+keypad modules on the
* market, such as those found in Nexcom's appliances.
*
* FIXME:
* - the initialization/deinitialization process is very dirty and should
* be rewritten. It may even be buggy.
*
* TODO:
* - document 24 keys keyboard (3 rows of 8 cols, 32 diodes + 2 inputs)
* - make the LCD a part of a virtual screen of Vx*Vy
* - make the inputs list smp-safe
* - change the keyboard to a double mapping : signals -> key_id -> values
* so that applications can change values without knowing signals
*
*/
#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
#include <linux/module.h>
#include <linux/types.h>
#include <linux/errno.h>
#include <linux/signal.h>
#include <linux/sched.h>
#include <linux/spinlock.h>
#include <linux/interrupt.h>
#include <linux/miscdevice.h>
#include <linux/slab.h>
#include <linux/ioport.h>
#include <linux/fcntl.h>
#include <linux/init.h>
#include <linux/delay.h>
#include <linux/kernel.h>
#include <linux/ctype.h>
#include <linux/parport.h>
#include <linux/list.h>
#include <linux/io.h>
#include <linux/uaccess.h>
#include <misc/charlcd.h>
#define KEYPAD_MINOR 185
#define LCD_MAXBYTES 256 /* max burst write */
#define KEYPAD_BUFFER 64
/* poll the keyboard this every second */
#define INPUT_POLL_TIME (HZ / 50)
/* a key starts to repeat after this times INPUT_POLL_TIME */
#define KEYPAD_REP_START (10)
/* a key repeats this times INPUT_POLL_TIME */
#define KEYPAD_REP_DELAY (2)
/* converts an r_str() input to an active high, bits string : 000BAOSE */
#define PNL_PINPUT(a) ((((unsigned char)(a)) ^ 0x7F) >> 3)
#define PNL_PBUSY 0x80 /* inverted input, active low */
#define PNL_PACK 0x40 /* direct input, active low */
#define PNL_POUTPA 0x20 /* direct input, active high */
#define PNL_PSELECD 0x10 /* direct input, active high */
#define PNL_PERRORP 0x08 /* direct input, active low */
#define PNL_PBIDIR 0x20 /* bi-directional ports */
/* high to read data in or-ed with data out */
#define PNL_PINTEN 0x10
#define PNL_PSELECP 0x08 /* inverted output, active low */
#define PNL_PINITP 0x04 /* direct output, active low */
#define PNL_PAUTOLF 0x02 /* inverted output, active low */
#define PNL_PSTROBE 0x01 /* inverted output */
#define PNL_PD0 0x01
#define PNL_PD1 0x02
#define PNL_PD2 0x04
#define PNL_PD3 0x08
#define PNL_PD4 0x10
#define PNL_PD5 0x20
#define PNL_PD6 0x40
#define PNL_PD7 0x80
#define PIN_NONE 0
#define PIN_STROBE 1
#define PIN_D0 2
#define PIN_D1 3
#define PIN_D2 4
#define PIN_D3 5
#define PIN_D4 6
#define PIN_D5 7
#define PIN_D6 8
#define PIN_D7 9
#define PIN_AUTOLF 14
#define PIN_INITP 16
#define PIN_SELECP 17
#define PIN_NOT_SET 127
#define NOT_SET -1
/* macros to simplify use of the parallel port */
#define r_ctr(x) (parport_read_control((x)->port))
#define r_dtr(x) (parport_read_data((x)->port))
#define r_str(x) (parport_read_status((x)->port))
#define w_ctr(x, y) (parport_write_control((x)->port, (y)))
#define w_dtr(x, y) (parport_write_data((x)->port, (y)))
/* this defines which bits are to be used and which ones to be ignored */
/* logical or of the output bits involved in the scan matrix */
static __u8 scan_mask_o;
/* logical or of the input bits involved in the scan matrix */
static __u8 scan_mask_i;
enum input_type {
INPUT_TYPE_STD,
INPUT_TYPE_KBD,
};
enum input_state {
INPUT_ST_LOW,
INPUT_ST_RISING,
INPUT_ST_HIGH,
INPUT_ST_FALLING,
};
struct logical_input {
struct list_head list;
__u64 mask;
__u64 value;
enum input_type type;
enum input_state state;
__u8 rise_time, fall_time;
__u8 rise_timer, fall_timer, high_timer;
union {
struct { /* valid when type == INPUT_TYPE_STD */
void (*press_fct)(int);
void (*release_fct)(int);
int press_data;
int release_data;
} std;
struct { /* valid when type == INPUT_TYPE_KBD */
char press_str[sizeof(void *) + sizeof(int)] __nonstring;
char repeat_str[sizeof(void *) + sizeof(int)] __nonstring;
char release_str[sizeof(void *) + sizeof(int)] __nonstring;
} kbd;
} u;
};
static LIST_HEAD(logical_inputs); /* list of all defined logical inputs */
/* physical contacts history
* Physical contacts are a 45 bits string of 9 groups of 5 bits each.
* The 8 lower groups correspond to output bits 0 to 7, and the 9th group
* corresponds to the ground.
* Within each group, bits are stored in the same order as read on the port :
* BAPSE (busy=4, ack=3, paper empty=2, select=1, error=0).
* So, each __u64 is represented like this :
* 0000000000000000000BAPSEBAPSEBAPSEBAPSEBAPSEBAPSEBAPSEBAPSEBAPSE
* <-----unused------><gnd><d07><d06><d05><d04><d03><d02><d01><d00>
*/
/* what has just been read from the I/O ports */
static __u64 phys_read;
/* previous phys_read */
static __u64 phys_read_prev;
/* stabilized phys_read (phys_read|phys_read_prev) */
static __u64 phys_curr;
/* previous phys_curr */
static __u64 phys_prev;
/* 0 means that at least one logical signal needs be computed */
static char inputs_stable;
/* these variables are specific to the keypad */
static struct {
bool enabled;
} keypad;
static char keypad_buffer[KEYPAD_BUFFER];
static int keypad_buflen;
static int keypad_start;
static char keypressed;
static wait_queue_head_t keypad_read_wait;
/* lcd-specific variables */
static struct {
bool enabled;
bool initialized;
int charset;
int proto;
/* TODO: use union here? */
struct {
int e;
int rs;
int rw;
int cl;
int da;
int bl;
} pins;
struct charlcd *charlcd;
} lcd;
/* Needed only for init */
static int selected_lcd_type = NOT_SET;
/*
* Bit masks to convert LCD signals to parallel port outputs.
* _d_ are values for data port, _c_ are for control port.
* [0] = signal OFF, [1] = signal ON, [2] = mask
*/
#define BIT_CLR 0
#define BIT_SET 1
#define BIT_MSK 2
#define BIT_STATES 3
/*
* one entry for each bit on the LCD
*/
#define LCD_BIT_E 0
#define LCD_BIT_RS 1
#define LCD_BIT_RW 2
#define LCD_BIT_BL 3
#define LCD_BIT_CL 4
#define LCD_BIT_DA 5
#define LCD_BITS 6
/*
* each bit can be either connected to a DATA or CTRL port
*/
#define LCD_PORT_C 0
#define LCD_PORT_D 1
#define LCD_PORTS 2
static unsigned char lcd_bits[LCD_PORTS][LCD_BITS][BIT_STATES];
/*
* LCD protocols
*/
#define LCD_PROTO_PARALLEL 0
#define LCD_PROTO_SERIAL 1
#define LCD_PROTO_TI_DA8XX_LCD 2
/*
* LCD character sets
*/
#define LCD_CHARSET_NORMAL 0
#define LCD_CHARSET_KS0074 1
/*
* LCD types
*/
#define LCD_TYPE_NONE 0
#define LCD_TYPE_CUSTOM 1
#define LCD_TYPE_OLD 2
#define LCD_TYPE_KS0074 3
#define LCD_TYPE_HANTRONIX 4
#define LCD_TYPE_NEXCOM 5
/*
* keypad types
*/
#define KEYPAD_TYPE_NONE 0
#define KEYPAD_TYPE_OLD 1
#define KEYPAD_TYPE_NEW 2
#define KEYPAD_TYPE_NEXCOM 3
/*
* panel profiles
*/
#define PANEL_PROFILE_CUSTOM 0
#define PANEL_PROFILE_OLD 1
#define PANEL_PROFILE_NEW 2
#define PANEL_PROFILE_HANTRONIX 3
#define PANEL_PROFILE_NEXCOM 4
#define PANEL_PROFILE_LARGE 5
/*
* Construct custom config from the kernel's configuration
*/
#define DEFAULT_PARPORT 0
#define DEFAULT_PROFILE PANEL_PROFILE_LARGE
#define DEFAULT_KEYPAD_TYPE KEYPAD_TYPE_OLD
#define DEFAULT_LCD_TYPE LCD_TYPE_OLD
#define DEFAULT_LCD_HEIGHT 2
#define DEFAULT_LCD_WIDTH 40
#define DEFAULT_LCD_BWIDTH 40
#define DEFAULT_LCD_HWIDTH 64
#define DEFAULT_LCD_CHARSET LCD_CHARSET_NORMAL
#define DEFAULT_LCD_PROTO LCD_PROTO_PARALLEL
#define DEFAULT_LCD_PIN_E PIN_AUTOLF
#define DEFAULT_LCD_PIN_RS PIN_SELECP
#define DEFAULT_LCD_PIN_RW PIN_INITP
#define DEFAULT_LCD_PIN_SCL PIN_STROBE
#define DEFAULT_LCD_PIN_SDA PIN_D0
#define DEFAULT_LCD_PIN_BL PIN_NOT_SET
#ifdef CONFIG_PANEL_PARPORT
#undef DEFAULT_PARPORT
#define DEFAULT_PARPORT CONFIG_PANEL_PARPORT
#endif
#ifdef CONFIG_PANEL_PROFILE
#undef DEFAULT_PROFILE
#define DEFAULT_PROFILE CONFIG_PANEL_PROFILE
#endif
#if DEFAULT_PROFILE == 0 /* custom */
#ifdef CONFIG_PANEL_KEYPAD
#undef DEFAULT_KEYPAD_TYPE
#define DEFAULT_KEYPAD_TYPE CONFIG_PANEL_KEYPAD
#endif
#ifdef CONFIG_PANEL_LCD
#undef DEFAULT_LCD_TYPE
#define DEFAULT_LCD_TYPE CONFIG_PANEL_LCD
#endif
#ifdef CONFIG_PANEL_LCD_HEIGHT
#undef DEFAULT_LCD_HEIGHT
#define DEFAULT_LCD_HEIGHT CONFIG_PANEL_LCD_HEIGHT
#endif
#ifdef CONFIG_PANEL_LCD_WIDTH
#undef DEFAULT_LCD_WIDTH
#define DEFAULT_LCD_WIDTH CONFIG_PANEL_LCD_WIDTH
#endif
#ifdef CONFIG_PANEL_LCD_BWIDTH
#undef DEFAULT_LCD_BWIDTH
#define DEFAULT_LCD_BWIDTH CONFIG_PANEL_LCD_BWIDTH
#endif
#ifdef CONFIG_PANEL_LCD_HWIDTH
#undef DEFAULT_LCD_HWIDTH
#define DEFAULT_LCD_HWIDTH CONFIG_PANEL_LCD_HWIDTH
#endif
#ifdef CONFIG_PANEL_LCD_CHARSET
#undef DEFAULT_LCD_CHARSET
#define DEFAULT_LCD_CHARSET CONFIG_PANEL_LCD_CHARSET
#endif
#ifdef CONFIG_PANEL_LCD_PROTO
#undef DEFAULT_LCD_PROTO
#define DEFAULT_LCD_PROTO CONFIG_PANEL_LCD_PROTO
#endif
#ifdef CONFIG_PANEL_LCD_PIN_E
#undef DEFAULT_LCD_PIN_E
#define DEFAULT_LCD_PIN_E CONFIG_PANEL_LCD_PIN_E
#endif
#ifdef CONFIG_PANEL_LCD_PIN_RS
#undef DEFAULT_LCD_PIN_RS
#define DEFAULT_LCD_PIN_RS CONFIG_PANEL_LCD_PIN_RS
#endif
#ifdef CONFIG_PANEL_LCD_PIN_RW
#undef DEFAULT_LCD_PIN_RW
#define DEFAULT_LCD_PIN_RW CONFIG_PANEL_LCD_PIN_RW
#endif
#ifdef CONFIG_PANEL_LCD_PIN_SCL
#undef DEFAULT_LCD_PIN_SCL
#define DEFAULT_LCD_PIN_SCL CONFIG_PANEL_LCD_PIN_SCL
#endif
#ifdef CONFIG_PANEL_LCD_PIN_SDA
#undef DEFAULT_LCD_PIN_SDA
#define DEFAULT_LCD_PIN_SDA CONFIG_PANEL_LCD_PIN_SDA
#endif
#ifdef CONFIG_PANEL_LCD_PIN_BL
#undef DEFAULT_LCD_PIN_BL
#define DEFAULT_LCD_PIN_BL CONFIG_PANEL_LCD_PIN_BL
#endif
#endif /* DEFAULT_PROFILE == 0 */
/* global variables */
/* Device single-open policy control */
static atomic_t keypad_available = ATOMIC_INIT(1);
static struct pardevice *pprt;
static int keypad_initialized;
static DEFINE_SPINLOCK(pprt_lock);
static struct timer_list scan_timer;
MODULE_DESCRIPTION("Generic parallel port LCD/Keypad driver");
static int parport = DEFAULT_PARPORT;
module_param(parport, int, 0000);
MODULE_PARM_DESC(parport, "Parallel port index (0=lpt1, 1=lpt2, ...)");
static int profile = DEFAULT_PROFILE;
module_param(profile, int, 0000);
MODULE_PARM_DESC(profile,
"1=16x2 old kp; 2=serial 16x2, new kp; 3=16x2 hantronix; "
"4=16x2 nexcom; default=40x2, old kp");
static int keypad_type = NOT_SET;
module_param(keypad_type, int, 0000);
MODULE_PARM_DESC(keypad_type,
"Keypad type: 0=none, 1=old 6 keys, 2=new 6+1 keys, 3=nexcom 4 keys");
static int lcd_type = NOT_SET;
module_param(lcd_type, int, 0000);
MODULE_PARM_DESC(lcd_type,
"LCD type: 0=none, 1=compiled-in, 2=old, 3=serial ks0074, 4=hantronix, 5=nexcom");
static int lcd_height = NOT_SET;
module_param(lcd_height, int, 0000);
MODULE_PARM_DESC(lcd_height, "Number of lines on the LCD");
static int lcd_width = NOT_SET;
module_param(lcd_width, int, 0000);
MODULE_PARM_DESC(lcd_width, "Number of columns on the LCD");
static int lcd_bwidth = NOT_SET; /* internal buffer width (usually 40) */
module_param(lcd_bwidth, int, 0000);
MODULE_PARM_DESC(lcd_bwidth, "Internal LCD line width (40)");
static int lcd_hwidth = NOT_SET; /* hardware buffer width (usually 64) */
module_param(lcd_hwidth, int, 0000);
MODULE_PARM_DESC(lcd_hwidth, "LCD line hardware address (64)");
static int lcd_charset = NOT_SET;
module_param(lcd_charset, int, 0000);
MODULE_PARM_DESC(lcd_charset, "LCD character set: 0=standard, 1=KS0074");
static int lcd_proto = NOT_SET;
module_param(lcd_proto, int, 0000);
MODULE_PARM_DESC(lcd_proto,
"LCD communication: 0=parallel (//), 1=serial, 2=TI LCD Interface");
/*
* These are the parallel port pins the LCD control signals are connected to.
* Set this to 0 if the signal is not used. Set it to its opposite value
* (negative) if the signal is negated. -MAXINT is used to indicate that the
* pin has not been explicitly specified.
*
* WARNING! no check will be performed about collisions with keypad !
*/
static int lcd_e_pin = PIN_NOT_SET;
module_param(lcd_e_pin, int, 0000);
MODULE_PARM_DESC(lcd_e_pin,
"# of the // port pin connected to LCD 'E' signal, with polarity (-17..17)");
static int lcd_rs_pin = PIN_NOT_SET;
module_param(lcd_rs_pin, int, 0000);
MODULE_PARM_DESC(lcd_rs_pin,
"# of the // port pin connected to LCD 'RS' signal, with polarity (-17..17)");
static int lcd_rw_pin = PIN_NOT_SET;
module_param(lcd_rw_pin, int, 0000);
MODULE_PARM_DESC(lcd_rw_pin,
"# of the // port pin connected to LCD 'RW' signal, with polarity (-17..17)");
static int lcd_cl_pin = PIN_NOT_SET;
module_param(lcd_cl_pin, int, 0000);
MODULE_PARM_DESC(lcd_cl_pin,
"# of the // port pin connected to serial LCD 'SCL' signal, with polarity (-17..17)");
static int lcd_da_pin = PIN_NOT_SET;
module_param(lcd_da_pin, int, 0000);
MODULE_PARM_DESC(lcd_da_pin,
"# of the // port pin connected to serial LCD 'SDA' signal, with polarity (-17..17)");
static int lcd_bl_pin = PIN_NOT_SET;
module_param(lcd_bl_pin, int, 0000);
MODULE_PARM_DESC(lcd_bl_pin,
"# of the // port pin connected to LCD backlight, with polarity (-17..17)");
/* Deprecated module parameters - consider not using them anymore */
static int lcd_enabled = NOT_SET;
module_param(lcd_enabled, int, 0000);
MODULE_PARM_DESC(lcd_enabled, "Deprecated option, use lcd_type instead");
static int keypad_enabled = NOT_SET;
module_param(keypad_enabled, int, 0000);
MODULE_PARM_DESC(keypad_enabled, "Deprecated option, use keypad_type instead");
/* for some LCD drivers (ks0074) we need a charset conversion table. */
static const unsigned char lcd_char_conv_ks0074[256] = {
/* 0|8 1|9 2|A 3|B 4|C 5|D 6|E 7|F */
/* 0x00 */ 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
/* 0x08 */ 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
/* 0x10 */ 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
/* 0x18 */ 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f,
/* 0x20 */ 0x20, 0x21, 0x22, 0x23, 0xa2, 0x25, 0x26, 0x27,
/* 0x28 */ 0x28, 0x29, 0x2a, 0x2b, 0x2c, 0x2d, 0x2e, 0x2f,
/* 0x30 */ 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37,
/* 0x38 */ 0x38, 0x39, 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f,
/* 0x40 */ 0xa0, 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47,
/* 0x48 */ 0x48, 0x49, 0x4a, 0x4b, 0x4c, 0x4d, 0x4e, 0x4f,
/* 0x50 */ 0x50, 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57,
/* 0x58 */ 0x58, 0x59, 0x5a, 0xfa, 0xfb, 0xfc, 0x1d, 0xc4,
/* 0x60 */ 0x96, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67,
/* 0x68 */ 0x68, 0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f,
/* 0x70 */ 0x70, 0x71, 0x72, 0x73, 0x74, 0x75, 0x76, 0x77,
/* 0x78 */ 0x78, 0x79, 0x7a, 0xfd, 0xfe, 0xff, 0xce, 0x20,
/* 0x80 */ 0x80, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87,
/* 0x88 */ 0x88, 0x89, 0x8a, 0x8b, 0x8c, 0x8d, 0x8e, 0x8f,
/* 0x90 */ 0x90, 0x91, 0x92, 0x93, 0x94, 0x95, 0x96, 0x97,
/* 0x98 */ 0x98, 0x99, 0x9a, 0x9b, 0x9c, 0x9d, 0x9e, 0x9f,
/* 0xA0 */ 0x20, 0x40, 0xb1, 0xa1, 0x24, 0xa3, 0xfe, 0x5f,
/* 0xA8 */ 0x22, 0xc8, 0x61, 0x14, 0x97, 0x2d, 0xad, 0x96,
/* 0xB0 */ 0x80, 0x8c, 0x82, 0x83, 0x27, 0x8f, 0x86, 0xdd,
/* 0xB8 */ 0x2c, 0x81, 0x6f, 0x15, 0x8b, 0x8a, 0x84, 0x60,
/* 0xC0 */ 0xe2, 0xe2, 0xe2, 0x5b, 0x5b, 0xae, 0xbc, 0xa9,
/* 0xC8 */ 0xc5, 0xbf, 0xc6, 0xf1, 0xe3, 0xe3, 0xe3, 0xe3,
/* 0xD0 */ 0x44, 0x5d, 0xa8, 0xe4, 0xec, 0xec, 0x5c, 0x78,
/* 0xD8 */ 0xab, 0xa6, 0xe5, 0x5e, 0x5e, 0xe6, 0xaa, 0xbe,
/* 0xE0 */ 0x7f, 0xe7, 0xaf, 0x7b, 0x7b, 0xaf, 0xbd, 0xc8,
/* 0xE8 */ 0xa4, 0xa5, 0xc7, 0xf6, 0xa7, 0xe8, 0x69, 0x69,
/* 0xF0 */ 0xed, 0x7d, 0xa8, 0xe4, 0xec, 0x5c, 0x5c, 0x25,
/* 0xF8 */ 0xac, 0xa6, 0xea, 0xef, 0x7e, 0xeb, 0xb2, 0x79,
};
static const char old_keypad_profile[][4][9] = {
{"S0", "Left\n", "Left\n", ""},
{"S1", "Down\n", "Down\n", ""},
{"S2", "Up\n", "Up\n", ""},
{"S3", "Right\n", "Right\n", ""},
{"S4", "Esc\n", "Esc\n", ""},
{"S5", "Ret\n", "Ret\n", ""},
{"", "", "", ""}
};
/* signals, press, repeat, release */
static const char new_keypad_profile[][4][9] = {
{"S0", "Left\n", "Left\n", ""},
{"S1", "Down\n", "Down\n", ""},
{"S2", "Up\n", "Up\n", ""},
{"S3", "Right\n", "Right\n", ""},
{"S4s5", "", "Esc\n", "Esc\n"},
{"s4S5", "", "Ret\n", "Ret\n"},
{"S4S5", "Help\n", "", ""},
/* add new signals above this line */
{"", "", "", ""}
};
/* signals, press, repeat, release */
static const char nexcom_keypad_profile[][4][9] = {
{"a-p-e-", "Down\n", "Down\n", ""},
{"a-p-E-", "Ret\n", "Ret\n", ""},
{"a-P-E-", "Esc\n", "Esc\n", ""},
{"a-P-e-", "Up\n", "Up\n", ""},
/* add new signals above this line */
{"", "", "", ""}
};
static const char (*keypad_profile)[4][9] = old_keypad_profile;
static DECLARE_BITMAP(bits, LCD_BITS);
static void lcd_get_bits(unsigned int port, int *val)
{
unsigned int bit, state;
for (bit = 0; bit < LCD_BITS; bit++) {
state = test_bit(bit, bits) ? BIT_SET : BIT_CLR;
*val &= lcd_bits[port][bit][BIT_MSK];
*val |= lcd_bits[port][bit][state];
}
}
/* sets data port bits according to current signals values */
static int set_data_bits(void)
{
int val;
val = r_dtr(pprt);
lcd_get_bits(LCD_PORT_D, &val);
w_dtr(pprt, val);
return val;
}
/* sets ctrl port bits according to current signals values */
static int set_ctrl_bits(void)
{
int val;
val = r_ctr(pprt);
lcd_get_bits(LCD_PORT_C, &val);
w_ctr(pprt, val);
return val;
}
/* sets ctrl & data port bits according to current signals values */
static void panel_set_bits(void)
{
set_data_bits();
set_ctrl_bits();
}
/*
* Converts a parallel port pin (from -25 to 25) to data and control ports
* masks, and data and control port bits. The signal will be considered
* unconnected if it's on pin 0 or an invalid pin (<-25 or >25).
*
* Result will be used this way :
* out(dport, in(dport) & d_val[2] | d_val[signal_state])
* out(cport, in(cport) & c_val[2] | c_val[signal_state])
*/
static void pin_to_bits(int pin, unsigned char *d_val, unsigned char *c_val)
{
int d_bit, c_bit, inv;
d_val[0] = 0;
c_val[0] = 0;
d_val[1] = 0;
c_val[1] = 0;
d_val[2] = 0xFF;
c_val[2] = 0xFF;
if (pin == 0)
return;
inv = (pin < 0);
if (inv)
pin = -pin;
d_bit = 0;
c_bit = 0;
switch (pin) {
case PIN_STROBE: /* strobe, inverted */
c_bit = PNL_PSTROBE;
inv = !inv;
break;
case PIN_D0...PIN_D7: /* D0 - D7 = 2 - 9 */
d_bit = 1 << (pin - 2);
break;
case PIN_AUTOLF: /* autofeed, inverted */
c_bit = PNL_PAUTOLF;
inv = !inv;
break;
case PIN_INITP: /* init, direct */
c_bit = PNL_PINITP;
break;
case PIN_SELECP: /* select_in, inverted */
c_bit = PNL_PSELECP;
inv = !inv;
break;
default: /* unknown pin, ignore */
break;
}
if (c_bit) {
c_val[2] &= ~c_bit;
c_val[!inv] = c_bit;
} else if (d_bit) {
d_val[2] &= ~d_bit;
d_val[!inv] = d_bit;
}
}
/*
* send a serial byte to the LCD panel. The caller is responsible for locking
* if needed.
*/
static void lcd_send_serial(int byte)
{
int bit;
/*
* the data bit is set on D0, and the clock on STROBE.
* LCD reads D0 on STROBE's rising edge.
*/
for (bit = 0; bit < 8; bit++) {
clear_bit(LCD_BIT_CL, bits); /* CLK low */
panel_set_bits();
if (byte & 1) {
set_bit(LCD_BIT_DA, bits);
} else {
clear_bit(LCD_BIT_DA, bits);
}
panel_set_bits();
udelay(2); /* maintain the data during 2 us before CLK up */
set_bit(LCD_BIT_CL, bits); /* CLK high */
panel_set_bits();
udelay(1); /* maintain the strobe during 1 us */
byte >>= 1;
}
}
/* turn the backlight on or off */
static void lcd_backlight(struct charlcd *charlcd, int on)
{
if (lcd.pins.bl == PIN_NONE)
return;
/* The backlight is activated by setting the AUTOFEED line to +5V */
spin_lock_irq(&pprt_lock);
if (on)
set_bit(LCD_BIT_BL, bits);
else
clear_bit(LCD_BIT_BL, bits);
panel_set_bits();
spin_unlock_irq(&pprt_lock);
}
/* send a command to the LCD panel in serial mode */
static void lcd_write_cmd_s(struct charlcd *charlcd, int cmd)
{
spin_lock_irq(&pprt_lock);
lcd_send_serial(0x1F); /* R/W=W, RS=0 */
lcd_send_serial(cmd & 0x0F);
lcd_send_serial((cmd >> 4) & 0x0F);
udelay(40); /* the shortest command takes at least 40 us */
spin_unlock_irq(&pprt_lock);
}
/* send data to the LCD panel in serial mode */
static void lcd_write_data_s(struct charlcd *charlcd, int data)
{
spin_lock_irq(&pprt_lock);
lcd_send_serial(0x5F); /* R/W=W, RS=1 */
lcd_send_serial(data & 0x0F);
lcd_send_serial((data >> 4) & 0x0F);
udelay(40); /* the shortest data takes at least 40 us */
spin_unlock_irq(&pprt_lock);
}
/* send a command to the LCD panel in 8 bits parallel mode */
static void lcd_write_cmd_p8(struct charlcd *charlcd, int cmd)
{
spin_lock_irq(&pprt_lock);
/* present the data to the data port */
w_dtr(pprt, cmd);
udelay(20); /* maintain the data during 20 us before the strobe */
set_bit(LCD_BIT_E, bits);
clear_bit(LCD_BIT_RS, bits);
clear_bit(LCD_BIT_RW, bits);
set_ctrl_bits();
udelay(40); /* maintain the strobe during 40 us */
clear_bit(LCD_BIT_E, bits);
set_ctrl_bits();
udelay(120); /* the shortest command takes at least 120 us */
spin_unlock_irq(&pprt_lock);
}
/* send data to the LCD panel in 8 bits parallel mode */
static void lcd_write_data_p8(struct charlcd *charlcd, int data)
{
spin_lock_irq(&pprt_lock);
/* present the data to the data port */
w_dtr(pprt, data);
udelay(20); /* maintain the data during 20 us before the strobe */
set_bit(LCD_BIT_E, bits);
set_bit(LCD_BIT_RS, bits);
clear_bit(LCD_BIT_RW, bits);
set_ctrl_bits();
udelay(40); /* maintain the strobe during 40 us */
clear_bit(LCD_BIT_E, bits);
set_ctrl_bits();
udelay(45); /* the shortest data takes at least 45 us */
spin_unlock_irq(&pprt_lock);
}
/* send a command to the TI LCD panel */
static void lcd_write_cmd_tilcd(struct charlcd *charlcd, int cmd)
{
spin_lock_irq(&pprt_lock);
/* present the data to the control port */
w_ctr(pprt, cmd);
udelay(60);
spin_unlock_irq(&pprt_lock);
}
/* send data to the TI LCD panel */
static void lcd_write_data_tilcd(struct charlcd *charlcd, int data)
{
spin_lock_irq(&pprt_lock);
/* present the data to the data port */
w_dtr(pprt, data);
udelay(60);
spin_unlock_irq(&pprt_lock);
}
/* fills the display with spaces and resets X/Y */
static void lcd_clear_fast_s(struct charlcd *charlcd)
{
int pos;
spin_lock_irq(&pprt_lock);
for (pos = 0; pos < charlcd->height * charlcd->hwidth; pos++) {
lcd_send_serial(0x5F); /* R/W=W, RS=1 */
lcd_send_serial(' ' & 0x0F);
lcd_send_serial((' ' >> 4) & 0x0F);
/* the shortest data takes at least 40 us */
udelay(40);
}
spin_unlock_irq(&pprt_lock);
}
/* fills the display with spaces and resets X/Y */
static void lcd_clear_fast_p8(struct charlcd *charlcd)
{
int pos;
spin_lock_irq(&pprt_lock);
for (pos = 0; pos < charlcd->height * charlcd->hwidth; pos++) {
/* present the data to the data port */
w_dtr(pprt, ' ');
/* maintain the data during 20 us before the strobe */
udelay(20);
set_bit(LCD_BIT_E, bits);
set_bit(LCD_BIT_RS, bits);
clear_bit(LCD_BIT_RW, bits);
set_ctrl_bits();
/* maintain the strobe during 40 us */
udelay(40);
clear_bit(LCD_BIT_E, bits);
set_ctrl_bits();
/* the shortest data takes at least 45 us */
udelay(45);
}
spin_unlock_irq(&pprt_lock);
}
/* fills the display with spaces and resets X/Y */
static void lcd_clear_fast_tilcd(struct charlcd *charlcd)
{
int pos;
spin_lock_irq(&pprt_lock);
for (pos = 0; pos < charlcd->height * charlcd->hwidth; pos++) {
/* present the data to the data port */
w_dtr(pprt, ' ');
udelay(60);
}
spin_unlock_irq(&pprt_lock);
}
static const struct charlcd_ops charlcd_serial_ops = {
.write_cmd = lcd_write_cmd_s,
.write_data = lcd_write_data_s,
.clear_fast = lcd_clear_fast_s,
.backlight = lcd_backlight,
};
static const struct charlcd_ops charlcd_parallel_ops = {
.write_cmd = lcd_write_cmd_p8,
.write_data = lcd_write_data_p8,
.clear_fast = lcd_clear_fast_p8,
.backlight = lcd_backlight,
};
static const struct charlcd_ops charlcd_tilcd_ops = {
.write_cmd = lcd_write_cmd_tilcd,
.write_data = lcd_write_data_tilcd,
.clear_fast = lcd_clear_fast_tilcd,
.backlight = lcd_backlight,
};
/* initialize the LCD driver */
static void lcd_init(void)
{
struct charlcd *charlcd;
charlcd = charlcd_alloc(0);
if (!charlcd)
return;
/*
* Init lcd struct with load-time values to preserve exact
* current functionality (at least for now).
*/
charlcd->height = lcd_height;
charlcd->width = lcd_width;
charlcd->bwidth = lcd_bwidth;
charlcd->hwidth = lcd_hwidth;
switch (selected_lcd_type) {
case LCD_TYPE_OLD:
/* parallel mode, 8 bits */
lcd.proto = LCD_PROTO_PARALLEL;
lcd.charset = LCD_CHARSET_NORMAL;
lcd.pins.e = PIN_STROBE;
lcd.pins.rs = PIN_AUTOLF;
charlcd->width = 40;
charlcd->bwidth = 40;
charlcd->hwidth = 64;
charlcd->height = 2;
break;
case LCD_TYPE_KS0074:
/* serial mode, ks0074 */
lcd.proto = LCD_PROTO_SERIAL;
lcd.charset = LCD_CHARSET_KS0074;
lcd.pins.bl = PIN_AUTOLF;
lcd.pins.cl = PIN_STROBE;
lcd.pins.da = PIN_D0;
charlcd->width = 16;
charlcd->bwidth = 40;
charlcd->hwidth = 16;
charlcd->height = 2;
break;
case LCD_TYPE_NEXCOM:
/* parallel mode, 8 bits, generic */
lcd.proto = LCD_PROTO_PARALLEL;
lcd.charset = LCD_CHARSET_NORMAL;
lcd.pins.e = PIN_AUTOLF;
lcd.pins.rs = PIN_SELECP;
lcd.pins.rw = PIN_INITP;
charlcd->width = 16;
charlcd->bwidth = 40;
charlcd->hwidth = 64;
charlcd->height = 2;
break;
case LCD_TYPE_CUSTOM:
/* customer-defined */
lcd.proto = DEFAULT_LCD_PROTO;
lcd.charset = DEFAULT_LCD_CHARSET;
/* default geometry will be set later */
break;
case LCD_TYPE_HANTRONIX:
/* parallel mode, 8 bits, hantronix-like */
default:
lcd.proto = LCD_PROTO_PARALLEL;
lcd.charset = LCD_CHARSET_NORMAL;
lcd.pins.e = PIN_STROBE;
lcd.pins.rs = PIN_SELECP;
charlcd->width = 16;
charlcd->bwidth = 40;
charlcd->hwidth = 64;
charlcd->height = 2;
break;
}
/* Overwrite with module params set on loading */
if (lcd_height != NOT_SET)
charlcd->height = lcd_height;
if (lcd_width != NOT_SET)
charlcd->width = lcd_width;
if (lcd_bwidth != NOT_SET)
charlcd->bwidth = lcd_bwidth;
if (lcd_hwidth != NOT_SET)
charlcd->hwidth = lcd_hwidth;
if (lcd_charset != NOT_SET)
lcd.charset = lcd_charset;
if (lcd_proto != NOT_SET)
lcd.proto = lcd_proto;
if (lcd_e_pin != PIN_NOT_SET)
lcd.pins.e = lcd_e_pin;
if (lcd_rs_pin != PIN_NOT_SET)
lcd.pins.rs = lcd_rs_pin;
if (lcd_rw_pin != PIN_NOT_SET)
lcd.pins.rw = lcd_rw_pin;
if (lcd_cl_pin != PIN_NOT_SET)
lcd.pins.cl = lcd_cl_pin;
if (lcd_da_pin != PIN_NOT_SET)
lcd.pins.da = lcd_da_pin;
if (lcd_bl_pin != PIN_NOT_SET)
lcd.pins.bl = lcd_bl_pin;
/* this is used to catch wrong and default values */
if (charlcd->width <= 0)
charlcd->width = DEFAULT_LCD_WIDTH;
if (charlcd->bwidth <= 0)
charlcd->bwidth = DEFAULT_LCD_BWIDTH;
if (charlcd->hwidth <= 0)
charlcd->hwidth = DEFAULT_LCD_HWIDTH;
if (charlcd->height <= 0)
charlcd->height = DEFAULT_LCD_HEIGHT;
if (lcd.proto == LCD_PROTO_SERIAL) { /* SERIAL */
charlcd->ops = &charlcd_serial_ops;
if (lcd.pins.cl == PIN_NOT_SET)
lcd.pins.cl = DEFAULT_LCD_PIN_SCL;
if (lcd.pins.da == PIN_NOT_SET)
lcd.pins.da = DEFAULT_LCD_PIN_SDA;
} else if (lcd.proto == LCD_PROTO_PARALLEL) { /* PARALLEL */
charlcd->ops = &charlcd_parallel_ops;
if (lcd.pins.e == PIN_NOT_SET)
lcd.pins.e = DEFAULT_LCD_PIN_E;
if (lcd.pins.rs == PIN_NOT_SET)
lcd.pins.rs = DEFAULT_LCD_PIN_RS;
if (lcd.pins.rw == PIN_NOT_SET)
lcd.pins.rw = DEFAULT_LCD_PIN_RW;
} else {
charlcd->ops = &charlcd_tilcd_ops;
}
if (lcd.pins.bl == PIN_NOT_SET)
lcd.pins.bl = DEFAULT_LCD_PIN_BL;
if (lcd.pins.e == PIN_NOT_SET)
lcd.pins.e = PIN_NONE;
if (lcd.pins.rs == PIN_NOT_SET)
lcd.pins.rs = PIN_NONE;
if (lcd.pins.rw == PIN_NOT_SET)
lcd.pins.rw = PIN_NONE;
if (lcd.pins.bl == PIN_NOT_SET)
lcd.pins.bl = PIN_NONE;
if (lcd.pins.cl == PIN_NOT_SET)
lcd.pins.cl = PIN_NONE;
if (lcd.pins.da == PIN_NOT_SET)
lcd.pins.da = PIN_NONE;
if (lcd.charset == NOT_SET)
lcd.charset = DEFAULT_LCD_CHARSET;
if (lcd.charset == LCD_CHARSET_KS0074)
charlcd->char_conv = lcd_char_conv_ks0074;
else
charlcd->char_conv = NULL;
pin_to_bits(lcd.pins.e, lcd_bits[LCD_PORT_D][LCD_BIT_E],
lcd_bits[LCD_PORT_C][LCD_BIT_E]);
pin_to_bits(lcd.pins.rs, lcd_bits[LCD_PORT_D][LCD_BIT_RS],
lcd_bits[LCD_PORT_C][LCD_BIT_RS]);
pin_to_bits(lcd.pins.rw, lcd_bits[LCD_PORT_D][LCD_BIT_RW],
lcd_bits[LCD_PORT_C][LCD_BIT_RW]);
pin_to_bits(lcd.pins.bl, lcd_bits[LCD_PORT_D][LCD_BIT_BL],
lcd_bits[LCD_PORT_C][LCD_BIT_BL]);
pin_to_bits(lcd.pins.cl, lcd_bits[LCD_PORT_D][LCD_BIT_CL],
lcd_bits[LCD_PORT_C][LCD_BIT_CL]);
pin_to_bits(lcd.pins.da, lcd_bits[LCD_PORT_D][LCD_BIT_DA],
lcd_bits[LCD_PORT_C][LCD_BIT_DA]);
lcd.charlcd = charlcd;
lcd.initialized = true;
}
/*
* These are the file operation function for user access to /dev/keypad
*/
static ssize_t keypad_read(struct file *file,
char __user *buf, size_t count, loff_t *ppos)
{
unsigned i = *ppos;
char __user *tmp = buf;
if (keypad_buflen == 0) {
if (file->f_flags & O_NONBLOCK)
return -EAGAIN;
if (wait_event_interruptible(keypad_read_wait,
keypad_buflen != 0))
return -EINTR;
}
for (; count-- > 0 && (keypad_buflen > 0);
++i, ++tmp, --keypad_buflen) {
put_user(keypad_buffer[keypad_start], tmp);
keypad_start = (keypad_start + 1) % KEYPAD_BUFFER;
}
*ppos = i;
return tmp - buf;
}
static int keypad_open(struct inode *inode, struct file *file)
{
int ret;
ret = -EBUSY;
if (!atomic_dec_and_test(&keypad_available))
goto fail; /* open only once at a time */
ret = -EPERM;
if (file->f_mode & FMODE_WRITE) /* device is read-only */
goto fail;
keypad_buflen = 0; /* flush the buffer on opening */
return 0;
fail:
atomic_inc(&keypad_available);
return ret;
}
static int keypad_release(struct inode *inode, struct file *file)
{
atomic_inc(&keypad_available);
return 0;
}
static const struct file_operations keypad_fops = {
.read = keypad_read, /* read */
.open = keypad_open, /* open */
.release = keypad_release, /* close */
.llseek = default_llseek,
};
static struct miscdevice keypad_dev = {
.minor = KEYPAD_MINOR,
.name = "keypad",
.fops = &keypad_fops,
};
static void keypad_send_key(const char *string, int max_len)
{
/* send the key to the device only if a process is attached to it. */
if (!atomic_read(&keypad_available)) {
while (max_len-- && keypad_buflen < KEYPAD_BUFFER && *string) {
keypad_buffer[(keypad_start + keypad_buflen++) %
KEYPAD_BUFFER] = *string++;
}
wake_up_interruptible(&keypad_read_wait);
}
}
/* this function scans all the bits involving at least one logical signal,
* and puts the results in the bitfield "phys_read" (one bit per established
* contact), and sets "phys_read_prev" to "phys_read".
*
* Note: to debounce input signals, we will only consider as switched a signal
* which is stable across 2 measures. Signals which are different between two
* reads will be kept as they previously were in their logical form (phys_prev).
* A signal which has just switched will have a 1 in
* (phys_read ^ phys_read_prev).
*/
static void phys_scan_contacts(void)
{
int bit, bitval;
char oldval;
char bitmask;
char gndmask;
phys_prev = phys_curr;
phys_read_prev = phys_read;
phys_read = 0; /* flush all signals */
/* keep track of old value, with all outputs disabled */
oldval = r_dtr(pprt) | scan_mask_o;
/* activate all keyboard outputs (active low) */
w_dtr(pprt, oldval & ~scan_mask_o);
/* will have a 1 for each bit set to gnd */
bitmask = PNL_PINPUT(r_str(pprt)) & scan_mask_i;
/* disable all matrix signals */
w_dtr(pprt, oldval);
/* now that all outputs are cleared, the only active input bits are
* directly connected to the ground
*/
/* 1 for each grounded input */
gndmask = PNL_PINPUT(r_str(pprt)) & scan_mask_i;
/* grounded inputs are signals 40-44 */
phys_read |= (__u64)gndmask << 40;
if (bitmask != gndmask) {
/*
* since clearing the outputs changed some inputs, we know
* that some input signals are currently tied to some outputs.
* So we'll scan them.
*/
for (bit = 0; bit < 8; bit++) {
bitval = BIT(bit);
if (!(scan_mask_o & bitval)) /* skip unused bits */
continue;
w_dtr(pprt, oldval & ~bitval); /* enable this output */
bitmask = PNL_PINPUT(r_str(pprt)) & ~gndmask;
phys_read |= (__u64)bitmask << (5 * bit);
}
w_dtr(pprt, oldval); /* disable all outputs */
}
/*
* this is easy: use old bits when they are flapping,
* use new ones when stable
*/
phys_curr = (phys_prev & (phys_read ^ phys_read_prev)) |
(phys_read & ~(phys_read ^ phys_read_prev));
}
static inline int input_state_high(struct logical_input *input)
{
#if 0
/* FIXME:
* this is an invalid test. It tries to catch
* transitions from single-key to multiple-key, but
* doesn't take into account the contacts polarity.
* The only solution to the problem is to parse keys
* from the most complex to the simplest combinations,
* and mark them as 'caught' once a combination
* matches, then unmatch it for all other ones.
*/
/* try to catch dangerous transitions cases :
* someone adds a bit, so this signal was a false
* positive resulting from a transition. We should
* invalidate the signal immediately and not call the
* release function.
* eg: 0 -(press A)-> A -(press B)-> AB : don't match A's release.
*/
if (((phys_prev & input->mask) == input->value) &&
((phys_curr & input->mask) > input->value)) {
input->state = INPUT_ST_LOW; /* invalidate */
return 1;
}
#endif
if ((phys_curr & input->mask) == input->value) {
if ((input->type == INPUT_TYPE_STD) &&
(input->high_timer == 0)) {
input->high_timer++;
if (input->u.std.press_fct)
input->u.std.press_fct(input->u.std.press_data);
} else if (input->type == INPUT_TYPE_KBD) {
/* will turn on the light */
keypressed = 1;
if (input->high_timer == 0) {
char *press_str = input->u.kbd.press_str;
if (press_str[0]) {
int s = sizeof(input->u.kbd.press_str);
keypad_send_key(press_str, s);
}
}
if (input->u.kbd.repeat_str[0]) {
char *repeat_str = input->u.kbd.repeat_str;
if (input->high_timer >= KEYPAD_REP_START) {
int s = sizeof(input->u.kbd.repeat_str);
input->high_timer -= KEYPAD_REP_DELAY;
keypad_send_key(repeat_str, s);
}
/* we will need to come back here soon */
inputs_stable = 0;
}
if (input->high_timer < 255)
input->high_timer++;
}
return 1;
}
/* else signal falling down. Let's fall through. */
input->state = INPUT_ST_FALLING;
input->fall_timer = 0;
return 0;
}
static inline void input_state_falling(struct logical_input *input)
{
#if 0
/* FIXME !!! same comment as in input_state_high */
if (((phys_prev & input->mask) == input->value) &&
((phys_curr & input->mask) > input->value)) {
input->state = INPUT_ST_LOW; /* invalidate */
return;
}
#endif
if ((phys_curr & input->mask) == input->value) {
if (input->type == INPUT_TYPE_KBD) {
/* will turn on the light */
keypressed = 1;
if (input->u.kbd.repeat_str[0]) {
char *repeat_str = input->u.kbd.repeat_str;
if (input->high_timer >= KEYPAD_REP_START) {
int s = sizeof(input->u.kbd.repeat_str);
input->high_timer -= KEYPAD_REP_DELAY;
keypad_send_key(repeat_str, s);
}
/* we will need to come back here soon */
inputs_stable = 0;
}
if (input->high_timer < 255)
input->high_timer++;
}
input->state = INPUT_ST_HIGH;
} else if (input->fall_timer >= input->fall_time) {
/* call release event */
if (input->type == INPUT_TYPE_STD) {
void (*release_fct)(int) = input->u.std.release_fct;
if (release_fct)
release_fct(input->u.std.release_data);
} else if (input->type == INPUT_TYPE_KBD) {
char *release_str = input->u.kbd.release_str;
if (release_str[0]) {
int s = sizeof(input->u.kbd.release_str);
keypad_send_key(release_str, s);
}
}
input->state = INPUT_ST_LOW;
} else {
input->fall_timer++;
inputs_stable = 0;
}
}
static void panel_process_inputs(void)
{
struct logical_input *input;
keypressed = 0;
inputs_stable = 1;
list_for_each_entry(input, &logical_inputs, list) {
switch (input->state) {
case INPUT_ST_LOW:
if ((phys_curr & input->mask) != input->value)
break;
/* if all needed ones were already set previously,
* this means that this logical signal has been
* activated by the releasing of another combined
* signal, so we don't want to match.
* eg: AB -(release B)-> A -(release A)-> 0 :
* don't match A.
*/
if ((phys_prev & input->mask) == input->value)
break;
input->rise_timer = 0;
input->state = INPUT_ST_RISING;
/* fall through */
case INPUT_ST_RISING:
if ((phys_curr & input->mask) != input->value) {
input->state = INPUT_ST_LOW;
break;
}
if (input->rise_timer < input->rise_time) {
inputs_stable = 0;
input->rise_timer++;
break;
}
input->high_timer = 0;
input->state = INPUT_ST_HIGH;
/* fall through */
case INPUT_ST_HIGH:
if (input_state_high(input))
break;
/* fall through */
case INPUT_ST_FALLING:
input_state_falling(input);
}
}
}
static void panel_scan_timer(struct timer_list *unused)
{
if (keypad.enabled && keypad_initialized) {
if (spin_trylock_irq(&pprt_lock)) {
phys_scan_contacts();
/* no need for the parport anymore */
spin_unlock_irq(&pprt_lock);
}
if (!inputs_stable || phys_curr != phys_prev)
panel_process_inputs();
}
if (keypressed && lcd.enabled && lcd.initialized)
charlcd_poke(lcd.charlcd);
mod_timer(&scan_timer, jiffies + INPUT_POLL_TIME);
}
static void init_scan_timer(void)
{
if (scan_timer.function)
return; /* already started */
timer_setup(&scan_timer, panel_scan_timer, 0);
scan_timer.expires = jiffies + INPUT_POLL_TIME;
add_timer(&scan_timer);
}
/* converts a name of the form "({BbAaPpSsEe}{01234567-})*" to a series of bits.
* if <omask> or <imask> are non-null, they will be or'ed with the bits
* corresponding to out and in bits respectively.
* returns 1 if ok, 0 if error (in which case, nothing is written).
*/
static u8 input_name2mask(const char *name, __u64 *mask, __u64 *value,
u8 *imask, u8 *omask)
{
const char sigtab[] = "EeSsPpAaBb";
u8 im, om;
__u64 m, v;
om = 0;
im = 0;
m = 0ULL;
v = 0ULL;
while (*name) {
int in, out, bit, neg;
const char *idx;
idx = strchr(sigtab, *name);
if (!idx)
return 0; /* input name not found */
in = idx - sigtab;
neg = (in & 1); /* odd (lower) names are negated */
in >>= 1;
im |= BIT(in);
name++;
if (*name >= '0' && *name <= '7') {
out = *name - '0';
om |= BIT(out);
} else if (*name == '-') {
out = 8;
} else {
return 0; /* unknown bit name */
}
bit = (out * 5) + in;
m |= 1ULL << bit;
if (!neg)
v |= 1ULL << bit;
name++;
}
*mask = m;
*value = v;
if (imask)
*imask |= im;
if (omask)
*omask |= om;
return 1;
}
/* tries to bind a key to the signal name <name>. The key will send the
* strings <press>, <repeat>, <release> for these respective events.
* Returns the pointer to the new key if ok, NULL if the key could not be bound.
*/
static struct logical_input *panel_bind_key(const char *name, const char *press,
const char *repeat,
const char *release)
{
struct logical_input *key;
key = kzalloc(sizeof(*key), GFP_KERNEL);
if (!key)
return NULL;
if (!input_name2mask(name, &key->mask, &key->value, &scan_mask_i,
&scan_mask_o)) {
kfree(key);
return NULL;
}
key->type = INPUT_TYPE_KBD;
key->state = INPUT_ST_LOW;
key->rise_time = 1;
key->fall_time = 1;
strncpy(key->u.kbd.press_str, press, sizeof(key->u.kbd.press_str));
strncpy(key->u.kbd.repeat_str, repeat, sizeof(key->u.kbd.repeat_str));
strncpy(key->u.kbd.release_str, release,
sizeof(key->u.kbd.release_str));
list_add(&key->list, &logical_inputs);
return key;
}
#if 0
/* tries to bind a callback function to the signal name <name>. The function
* <press_fct> will be called with the <press_data> arg when the signal is
* activated, and so on for <release_fct>/<release_data>
* Returns the pointer to the new signal if ok, NULL if the signal could not
* be bound.
*/
static struct logical_input *panel_bind_callback(char *name,
void (*press_fct)(int),
int press_data,
void (*release_fct)(int),
int release_data)
{
struct logical_input *callback;
callback = kmalloc(sizeof(*callback), GFP_KERNEL);
if (!callback)
return NULL;
memset(callback, 0, sizeof(struct logical_input));
if (!input_name2mask(name, &callback->mask, &callback->value,
&scan_mask_i, &scan_mask_o))
return NULL;
callback->type = INPUT_TYPE_STD;
callback->state = INPUT_ST_LOW;
callback->rise_time = 1;
callback->fall_time = 1;
callback->u.std.press_fct = press_fct;
callback->u.std.press_data = press_data;
callback->u.std.release_fct = release_fct;
callback->u.std.release_data = release_data;
list_add(&callback->list, &logical_inputs);
return callback;
}
#endif
static void keypad_init(void)
{
int keynum;
init_waitqueue_head(&keypad_read_wait);
keypad_buflen = 0; /* flushes any eventual noisy keystroke */
/* Let's create all known keys */
for (keynum = 0; keypad_profile[keynum][0][0]; keynum++) {
panel_bind_key(keypad_profile[keynum][0],
keypad_profile[keynum][1],
keypad_profile[keynum][2],
keypad_profile[keynum][3]);
}
init_scan_timer();
keypad_initialized = 1;
}
/**************************************************/
/* device initialization */
/**************************************************/
static void panel_attach(struct parport *port)
{
struct pardev_cb panel_cb;
if (port->number != parport)
return;
if (pprt) {
pr_err("%s: port->number=%d parport=%d, already registered!\n",
__func__, port->number, parport);
return;
}
memset(&panel_cb, 0, sizeof(panel_cb));
panel_cb.private = &pprt;
/* panel_cb.flags = 0 should be PARPORT_DEV_EXCL? */
pprt = parport_register_dev_model(port, "panel", &panel_cb, 0);
if (!pprt) {
pr_err("%s: port->number=%d parport=%d, parport_register_device() failed\n",
__func__, port->number, parport);
return;
}
if (parport_claim(pprt)) {
pr_err("could not claim access to parport%d. Aborting.\n",
parport);
goto err_unreg_device;
}
/* must init LCD first, just in case an IRQ from the keypad is
* generated at keypad init
*/
if (lcd.enabled) {
lcd_init();
if (!lcd.charlcd || charlcd_register(lcd.charlcd))
goto err_unreg_device;
}
if (keypad.enabled) {
keypad_init();
if (misc_register(&keypad_dev))
goto err_lcd_unreg;
}
return;
err_lcd_unreg:
if (lcd.enabled)
charlcd_unregister(lcd.charlcd);
err_unreg_device:
kfree(lcd.charlcd);
lcd.charlcd = NULL;
parport_unregister_device(pprt);
pprt = NULL;
}
static void panel_detach(struct parport *port)
{
if (port->number != parport)
return;
if (!pprt) {
pr_err("%s: port->number=%d parport=%d, nothing to unregister.\n",
__func__, port->number, parport);
return;
}
if (scan_timer.function)
del_timer_sync(&scan_timer);
if (keypad.enabled) {
misc_deregister(&keypad_dev);
keypad_initialized = 0;
}
if (lcd.enabled) {
charlcd_unregister(lcd.charlcd);
lcd.initialized = false;
kfree(lcd.charlcd);
lcd.charlcd = NULL;
}
/* TODO: free all input signals */
parport_release(pprt);
parport_unregister_device(pprt);
pprt = NULL;
}
static struct parport_driver panel_driver = {
.name = "panel",
.match_port = panel_attach,
.detach = panel_detach,
.devmodel = true,
};
/* init function */
static int __init panel_init_module(void)
{
int selected_keypad_type = NOT_SET, err;
/* take care of an eventual profile */
switch (profile) {
case PANEL_PROFILE_CUSTOM:
/* custom profile */
selected_keypad_type = DEFAULT_KEYPAD_TYPE;
selected_lcd_type = DEFAULT_LCD_TYPE;
break;
case PANEL_PROFILE_OLD:
/* 8 bits, 2*16, old keypad */
selected_keypad_type = KEYPAD_TYPE_OLD;
selected_lcd_type = LCD_TYPE_OLD;
/* TODO: This two are a little hacky, sort it out later */
if (lcd_width == NOT_SET)
lcd_width = 16;
if (lcd_hwidth == NOT_SET)
lcd_hwidth = 16;
break;
case PANEL_PROFILE_NEW:
/* serial, 2*16, new keypad */
selected_keypad_type = KEYPAD_TYPE_NEW;
selected_lcd_type = LCD_TYPE_KS0074;
break;
case PANEL_PROFILE_HANTRONIX:
/* 8 bits, 2*16 hantronix-like, no keypad */
selected_keypad_type = KEYPAD_TYPE_NONE;
selected_lcd_type = LCD_TYPE_HANTRONIX;
break;
case PANEL_PROFILE_NEXCOM:
/* generic 8 bits, 2*16, nexcom keypad, eg. Nexcom. */
selected_keypad_type = KEYPAD_TYPE_NEXCOM;
selected_lcd_type = LCD_TYPE_NEXCOM;
break;
case PANEL_PROFILE_LARGE:
/* 8 bits, 2*40, old keypad */
selected_keypad_type = KEYPAD_TYPE_OLD;
selected_lcd_type = LCD_TYPE_OLD;
break;
}
/*
* Overwrite selection with module param values (both keypad and lcd),
* where the deprecated params have lower prio.
*/
if (keypad_enabled != NOT_SET)
selected_keypad_type = keypad_enabled;
if (keypad_type != NOT_SET)
selected_keypad_type = keypad_type;
keypad.enabled = (selected_keypad_type > 0);
if (lcd_enabled != NOT_SET)
selected_lcd_type = lcd_enabled;
if (lcd_type != NOT_SET)
selected_lcd_type = lcd_type;
lcd.enabled = (selected_lcd_type > 0);
if (lcd.enabled) {
/*
* Init lcd struct with load-time values to preserve exact
* current functionality (at least for now).
*/
lcd.charset = lcd_charset;
lcd.proto = lcd_proto;
lcd.pins.e = lcd_e_pin;
lcd.pins.rs = lcd_rs_pin;
lcd.pins.rw = lcd_rw_pin;
lcd.pins.cl = lcd_cl_pin;
lcd.pins.da = lcd_da_pin;
lcd.pins.bl = lcd_bl_pin;
}
switch (selected_keypad_type) {
case KEYPAD_TYPE_OLD:
keypad_profile = old_keypad_profile;
break;
case KEYPAD_TYPE_NEW:
keypad_profile = new_keypad_profile;
break;
case KEYPAD_TYPE_NEXCOM:
keypad_profile = nexcom_keypad_profile;
break;
default:
keypad_profile = NULL;
break;
}
if (!lcd.enabled && !keypad.enabled) {
/* no device enabled, let's exit */
pr_err("panel driver disabled.\n");
return -ENODEV;
}
err = parport_register_driver(&panel_driver);
if (err) {
pr_err("could not register with parport. Aborting.\n");
return err;
}
if (pprt)
pr_info("panel driver registered on parport%d (io=0x%lx).\n",
parport, pprt->port->base);
else
pr_info("panel driver not yet registered\n");
return 0;
}
static void __exit panel_cleanup_module(void)
{
parport_unregister_driver(&panel_driver);
}
module_init(panel_init_module);
module_exit(panel_cleanup_module);
MODULE_AUTHOR("Willy Tarreau");
MODULE_LICENSE("GPL");
/*
* Local variables:
* c-indent-level: 4
* tab-width: 8
* End:
*/