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|
/*
* Copyright 2004-2010 Freescale Semiconductor, Inc. All Rights Reserved.
*/
/*
* The code contained herein is licensed under the GNU General Public
* License. You may obtain a copy of the GNU General Public License
* Version 2 or later at the following locations:
*
* http://www.opensource.org/licenses/gpl-license.html
* http://www.gnu.org/copyleft/gpl.html
*/
/*!
* @file mxc_keyb.c
*
* @brief Driver for the Freescale Semiconductor MXC keypad port.
*
* The keypad driver is designed as a standard Input driver which interacts
* with low level keypad port hardware. Upon opening, the Keypad driver
* initializes the keypad port. When the keypad interrupt happens the driver
* calles keypad polling timer and scans the keypad matrix for key
* press/release. If all key press/release happened it comes out of timer and
* waits for key press interrupt. The scancode for key press and release events
* are passed to Input subsytem.
*
* @ingroup keypad
*/
/*!
* Comment KPP_DEBUG to disable debug messages
*/
#define KPP_DEBUG 0
#if KPP_DEBUG
#define DEBUG
#include <linux/kernel.h>
#endif
#include <linux/module.h>
#include <linux/sched.h>
#include <linux/mm.h>
#include <linux/init.h>
#include <asm/io.h>
#include <asm/uaccess.h>
#include <mach/hardware.h>
#include <linux/kd.h>
#include <linux/fs.h>
#include <linux/kbd_kern.h>
#include <linux/ioctl.h>
#include <linux/poll.h>
#include <linux/interrupt.h>
#include <linux/timer.h>
#include <linux/input.h>
#include <linux/miscdevice.h>
#include <linux/platform_device.h>
#include <linux/delay.h>
#include <linux/clk.h>
#include <asm/mach/keypad.h>
/*!
* Keypad Module Name
*/
#define MOD_NAME "mxckpd"
/*!
* XLATE mode selection
*/
#define KEYPAD_XLATE 0
/*!
* RAW mode selection
*/
#define KEYPAD_RAW 1
/*!
* Maximum number of keys.
*/
#define MAXROW 8
#define MAXCOL 8
#define MXC_MAXKEY (MAXROW * MAXCOL)
/*!
* This define indicates break scancode for every key release. A constant
* of 128 is added to the key press scancode.
*/
#define MXC_KEYRELEASE 128
/*
* _reg_KPP_KPCR _reg_KPP_KPSR _reg_KPP_KDDR _reg_KPP_KPDR
* The offset of Keypad Control Register Address
*/
#define KPCR 0x00
/*
* The offset of Keypad Status Register Address
*/
#define KPSR 0x02
/*
* The offset of Keypad Data Direction Address
*/
#define KDDR 0x04
/*
* The offset of Keypad Data Register
*/
#define KPDR 0x06
/*
* Key Press Interrupt Status bit
*/
#define KBD_STAT_KPKD 0x01
/*
* Key Release Interrupt Status bit
*/
#define KBD_STAT_KPKR 0x02
/*
* Key Depress Synchronizer Chain Status bit
*/
#define KBD_STAT_KDSC 0x04
/*
* Key Release Synchronizer Status bit
*/
#define KBD_STAT_KRSS 0x08
/*
* Key Depress Interrupt Enable Status bit
*/
#define KBD_STAT_KDIE 0x100
/*
* Key Release Interrupt Enable
*/
#define KBD_STAT_KRIE 0x200
/*
* Keypad Clock Enable
*/
#define KBD_STAT_KPPEN 0x400
/*!
* Buffer size of keypad queue. Should be a power of 2.
*/
#define KPP_BUF_SIZE 128
/*!
* Test whether bit is set for integer c
*/
#define TEST_BIT(c, n) ((c) & (0x1 << (n)))
/*!
* Set nth bit in the integer c
*/
#define BITSET(c, n) ((c) | (1 << (n)))
/*!
* Reset nth bit in the integer c
*/
#define BITRESET(c, n) ((c) & ~(1 << (n)))
/*!
* This enum represents the keypad state machine to maintain debounce logic
* for key press/release.
*/
enum KeyState {
/*!
* Key press state.
*/
KStateUp,
/*!
* Key press debounce state.
*/
KStateFirstDown,
/*!
* Key release state.
*/
KStateDown,
/*!
* Key release debounce state.
*/
KStateFirstUp
};
/*!
* Keypad Private Data Structure
*/
struct keypad_priv {
/*!
* Keypad state machine.
*/
enum KeyState iKeyState;
/*!
* Number of rows configured in the keypad matrix
*/
unsigned long kpp_rows;
/*!
* Number of Columns configured in the keypad matrix
*/
unsigned long kpp_cols;
/*!
* Timer used for Keypad polling.
*/
struct timer_list poll_timer;
/*!
* The base address
*/
void __iomem *base;
};
/*!
* This structure holds the keypad private data structure.
*/
static struct keypad_priv kpp_dev;
/*! Indicates if the key pad device is enabled. */
static unsigned int key_pad_enabled;
/*! Input device structure. */
static struct input_dev *mxckbd_dev = NULL;
/*! KPP clock handle. */
static struct clk *kpp_clk;
/*! This static variable indicates whether a key event is pressed/released. */
static unsigned short KPress;
/*! cur_rcmap and prev_rcmap array is used to detect key press and release. */
static unsigned short *cur_rcmap; /* max 64 bits (8x8 matrix) */
static unsigned short *prev_rcmap;
/*!
* Debounce polling period(10ms) in system ticks.
*/
static unsigned short KScanRate = (10 * HZ) / 1000;
static struct keypad_data *keypad;
static int has_leaning_key;
/*!
* These arrays are used to store press and release scancodes.
*/
static short **press_scancode;
static short **release_scancode;
static const unsigned short *mxckpd_keycodes;
static unsigned short mxckpd_keycodes_size;
#define press_left_code 30
#define press_right_code 29
#define press_up_code 28
#define press_down_code 27
#define rel_left_code 158
#define rel_right_code 157
#define rel_up_code 156
#define rel_down_code 155
/*!
* These functions are used to configure and the GPIO pins for keypad to
* activate and deactivate it.
*/
extern void gpio_keypad_active(void);
extern void gpio_keypad_inactive(void);
/*!
* This function is called for generating scancodes for key press and
* release on keypad for the board.
*
* @param row Keypad row pressed on the keypad matrix.
* @param col Keypad col pressed on the keypad matrix.
* @param press Indicated key press/release.
*
* @return Key press/release Scancode.
*/
static signed short mxc_scan_matrix_leaning_key(int row, int col, int press)
{
static unsigned first_row;
static unsigned first_set = 0, flag = 0;
signed short scancode = -1;
if (press) {
if ((3 == col) && ((3 == row) ||
(4 == row) || (5 == row) || (6 == row))) {
if (first_set == 0) {
first_set = 1;
first_row = row;
} else {
first_set = 0;
if (((first_row == 6) || (first_row == 3))
&& ((row == 6) || (row == 3)))
scancode = press_down_code;
else if (((first_row == 3) || (first_row == 5))
&& ((row == 3) || (row == 5)))
scancode = press_left_code;
else if (((first_row == 6) || (first_row == 4))
&& ((row == 6) || (row == 4)))
scancode = press_right_code;
else if (((first_row == 4) || (first_row == 5))
&& ((row == 4) || (row == 5)))
scancode = press_up_code;
KPress = 1;
kpp_dev.iKeyState = KStateUp;
pr_debug("Press (%d, %d) scan=%d Kpress=%d\n",
row, col, scancode, KPress);
}
} else {
/*
* check for other keys only
* if the cursor key presses
* are not detected may be
* this needs better logic
*/
if ((0 == (cur_rcmap[3] & BITSET(0, 3))) &&
(0 == (cur_rcmap[4] & BITSET(0, 3))) &&
(0 == (cur_rcmap[5] & BITSET(0, 3))) &&
(0 == (cur_rcmap[6] & BITSET(0, 3)))) {
scancode = ((col * kpp_dev.kpp_rows) + row);
KPress = 1;
kpp_dev.iKeyState = KStateUp;
flag = 1;
pr_debug("Press (%d, %d) scan=%d Kpress=%d\n",
row, col, scancode, KPress);
}
}
} else {
if ((flag == 0) && (3 == col)
&& ((3 == row) || (4 == row) || (5 == row)
|| (6 == row))) {
if (first_set == 0) {
first_set = 1;
first_row = row;
} else {
first_set = 0;
if (((first_row == 6) || (first_row == 3))
&& ((row == 6) || (row == 3)))
scancode = rel_down_code;
else if (((first_row == 3) || (first_row == 5))
&& ((row == 3) || (row == 5)))
scancode = rel_left_code;
else if (((first_row == 6) || (first_row == 4))
&& ((row == 6) || (row == 4)))
scancode = rel_right_code;
else if (((first_row == 4) || (first_row == 5))
&& ((row == 4) || (row == 5)))
scancode = rel_up_code;
KPress = 0;
kpp_dev.iKeyState = KStateDown;
pr_debug("Release (%d, %d) scan=%d Kpress=%d\n",
row, col, scancode, KPress);
}
} else {
/*
* check for other keys only
* if the cursor key presses
* are not detected may be
* this needs better logic
*/
if ((0 == (prev_rcmap[3] & BITSET(0, 3))) &&
(0 == (prev_rcmap[4] & BITSET(0, 3))) &&
(0 == (cur_rcmap[5] & BITSET(0, 3))) &&
(0 == (cur_rcmap[6] & BITSET(0, 3)))) {
scancode = ((col * kpp_dev.kpp_rows) + row) +
MXC_KEYRELEASE;
KPress = 0;
flag = 0;
kpp_dev.iKeyState = KStateDown;
pr_debug("Release (%d, %d) scan=%d Kpress=%d\n",
row, col, scancode, KPress);
}
}
}
return scancode;
}
/*!
* This function is called to scan the keypad matrix to find out the key press
* and key release events. Make scancode and break scancode are generated for
* key press and key release events.
*
* The following scanning sequence are done for
* keypad row and column scanning,
* -# Write 1's to KPDR[15:8], setting column data to 1's
* -# Configure columns as totem pole outputs(for quick discharging of keypad
* capacitance)
* -# Configure columns as open-drain
* -# Write a single column to 0, others to 1.
* -# Sample row inputs and save data. Multiple key presses can be detected on
* a single column.
* -# Repeat steps the above steps for remaining columns.
* -# Return all columns to 0 in preparation for standby mode.
* -# Clear KPKD and KPKR status bit(s) by writing to a 1,
* Set the KPKR synchronizer chain by writing "1" to KRSS register,
* Clear the KPKD synchronizer chain by writing "1" to KDSC register
*
* @result Number of key pressed/released.
*/
static int mxc_kpp_scan_matrix(void)
{
unsigned short reg_val;
int col, row;
short scancode = 0;
int keycnt = 0; /* How many keys are still pressed */
/*
* wmb() linux kernel function which guarantees orderings in write
* operations
*/
wmb();
/* save cur keypad matrix to prev */
memcpy(prev_rcmap, cur_rcmap, kpp_dev.kpp_rows * sizeof(prev_rcmap[0]));
memset(cur_rcmap, 0, kpp_dev.kpp_rows * sizeof(cur_rcmap[0]));
for (col = 0; col < kpp_dev.kpp_cols; col++) { /* Col */
/* 2. Write 1.s to KPDR[15:8] setting column data to 1.s */
reg_val = __raw_readw(kpp_dev.base + KPDR);
reg_val |= 0xff00;
__raw_writew(reg_val, kpp_dev.base + KPDR);
/*
* 3. Configure columns as totem pole outputs(for quick
* discharging of keypad capacitance)
*/
reg_val = __raw_readw(kpp_dev.base + KPCR);
reg_val &= 0x00ff;
__raw_writew(reg_val, kpp_dev.base + KPCR);
udelay(2);
/*
* 4. Configure columns as open-drain
*/
reg_val = __raw_readw(kpp_dev.base + KPCR);
reg_val |= ((1 << kpp_dev.kpp_cols) - 1) << 8;
__raw_writew(reg_val, kpp_dev.base + KPCR);
/*
* 5. Write a single column to 0, others to 1.
* 6. Sample row inputs and save data. Multiple key presses
* can be detected on a single column.
* 7. Repeat steps 2 - 6 for remaining columns.
*/
/* Col bit starts at 8th bit in KPDR */
reg_val = __raw_readw(kpp_dev.base + KPDR);
reg_val &= ~(1 << (8 + col));
__raw_writew(reg_val, kpp_dev.base + KPDR);
/* Delay added to avoid propagating the 0 from column to row
* when scanning. */
udelay(5);
/* Read row input */
reg_val = __raw_readw(kpp_dev.base + KPDR);
for (row = 0; row < kpp_dev.kpp_rows; row++) { /* sample row */
if (TEST_BIT(reg_val, row) == 0) {
cur_rcmap[row] = BITSET(cur_rcmap[row], col);
keycnt++;
}
}
}
/*
* 8. Return all columns to 0 in preparation for standby mode.
* 9. Clear KPKD and KPKR status bit(s) by writing to a .1.,
* set the KPKR synchronizer chain by writing "1" to KRSS register,
* clear the KPKD synchronizer chain by writing "1" to KDSC register
*/
reg_val = 0x00;
__raw_writew(reg_val, kpp_dev.base + KPDR);
reg_val = __raw_readw(kpp_dev.base + KPDR);
reg_val = __raw_readw(kpp_dev.base + KPSR);
reg_val |= KBD_STAT_KPKD | KBD_STAT_KPKR | KBD_STAT_KRSS |
KBD_STAT_KDSC;
__raw_writew(reg_val, kpp_dev.base + KPSR);
/* Check key press status change */
/*
* prev_rcmap array will contain the previous status of the keypad
* matrix. cur_rcmap array will contains the present status of the
* keypad matrix. If a bit is set in the array, that (row, col) bit is
* pressed, else it is not pressed.
*
* XORing these two variables will give us the change in bit for
* particular row and column. If a bit is set in XOR output, then that
* (row, col) has a change of status from the previous state. From
* the diff variable the key press and key release of row and column
* are found out.
*
* If the key press is determined then scancode for key pressed
* can be generated using the following statement:
* scancode = ((row * 8) + col);
*
* If the key release is determined then scancode for key release
* can be generated using the following statement:
* scancode = ((row * 8) + col) + MXC_KEYRELEASE;
*/
for (row = 0; row < kpp_dev.kpp_rows; row++) {
unsigned char diff;
/*
* Calculate the change in the keypad row status
*/
diff = prev_rcmap[row] ^ cur_rcmap[row];
for (col = 0; col < kpp_dev.kpp_cols; col++) {
if ((diff >> col) & 0x1) {
/* There is a status change on col */
if ((prev_rcmap[row] & BITSET(0, col)) == 0) {
/*
* Previous state is 0, so now
* a key is pressed
*/
if (has_leaning_key) {
scancode =
mxc_scan_matrix_leaning_key
(row, col, 1);
} else {
scancode =
((row * kpp_dev.kpp_cols) +
col);
KPress = 1;
kpp_dev.iKeyState = KStateUp;
}
pr_debug("Press (%d, %d) scan=%d "
"Kpress=%d\n",
row, col, scancode, KPress);
press_scancode[row][col] =
(short)scancode;
} else {
/*
* Previous state is not 0, so
* now a key is released
*/
if (has_leaning_key) {
scancode =
mxc_scan_matrix_leaning_key
(row, col, 0);
} else {
scancode =
(row * kpp_dev.kpp_cols) +
col + MXC_KEYRELEASE;
KPress = 0;
kpp_dev.iKeyState = KStateDown;
}
pr_debug
("Release (%d, %d) scan=%d Kpress=%d\n",
row, col, scancode, KPress);
release_scancode[row][col] =
(short)scancode;
keycnt++;
}
}
}
}
/*
* This switch case statement is the
* implementation of state machine of debounce
* logic for key press/release.
* The explaination of state machine is as
* follows:
*
* KStateUp State:
* This is in intial state of the state machine
* this state it checks for any key presses.
* The key press can be checked using the
* variable KPress. If KPress is set, then key
* press is identified and switches the to
* KStateFirstDown state for key press to
* debounce.
*
* KStateFirstDown:
* After debounce delay(10ms), if the KPress is
* still set then pass scancode generated to
* input device and change the state to
* KStateDown, else key press debounce is not
* satisfied so change the state to KStateUp.
*
* KStateDown:
* In this state it checks for any key release.
* If KPress variable is cleared, then key
* release is indicated and so, switch the
* state to KStateFirstUp else to state
* KStateDown.
*
* KStateFirstUp:
* After debounce delay(10ms), if the KPress is
* still reset then pass the key release
* scancode to input device and change
* the state to KStateUp else key release is
* not satisfied so change the state to
* KStateDown.
*/
switch (kpp_dev.iKeyState) {
case KStateUp:
if (KPress) {
/* First Down (must debounce). */
kpp_dev.iKeyState = KStateFirstDown;
} else {
/* Still UP.(NO Changes) */
kpp_dev.iKeyState = KStateUp;
}
break;
case KStateFirstDown:
if (KPress) {
for (row = 0; row < kpp_dev.kpp_rows; row++) {
for (col = 0; col < kpp_dev.kpp_cols; col++) {
if ((press_scancode[row][col] != -1)) {
/* Still Down, so add scancode */
scancode =
press_scancode[row][col];
input_event(mxckbd_dev, EV_KEY,
mxckpd_keycodes
[scancode], 1);
if (mxckpd_keycodes[scancode] ==
KEY_LEFTSHIFT) {
input_event(mxckbd_dev,
EV_KEY,
KEY_3, 1);
}
kpp_dev.iKeyState = KStateDown;
press_scancode[row][col] = -1;
}
}
}
} else {
/* Just a bounce */
kpp_dev.iKeyState = KStateUp;
}
break;
case KStateDown:
if (KPress) {
/* Still down (no change) */
kpp_dev.iKeyState = KStateDown;
} else {
/* First Up. Must debounce */
kpp_dev.iKeyState = KStateFirstUp;
}
break;
case KStateFirstUp:
if (KPress) {
/* Just a bounce */
kpp_dev.iKeyState = KStateDown;
} else {
for (row = 0; row < kpp_dev.kpp_rows; row++) {
for (col = 0; col < kpp_dev.kpp_cols; col++) {
if ((release_scancode[row][col] != -1)) {
scancode =
release_scancode[row][col];
scancode =
scancode - MXC_KEYRELEASE;
input_event(mxckbd_dev, EV_KEY,
mxckpd_keycodes
[scancode], 0);
if (mxckpd_keycodes[scancode] ==
KEY_LEFTSHIFT) {
input_event(mxckbd_dev,
EV_KEY,
KEY_3, 0);
}
kpp_dev.iKeyState = KStateUp;
release_scancode[row][col] = -1;
}
}
}
}
break;
default:
return -EBADRQC;
break;
}
return keycnt;
}
/*!
* This function is called to start the timer for scanning the keypad if there
* is any key press. Currently this interval is set to 10 ms. When there are
* no keys pressed on the keypad we return back, waiting for a keypad key
* press interrupt.
*
* @param data Opaque data passed back by kernel. Not used.
*/
static void mxc_kpp_handle_timer(unsigned long data)
{
unsigned short reg_val;
int i;
if (key_pad_enabled == 0) {
return;
}
if (mxc_kpp_scan_matrix() == 0) {
/*
* Stop scanning and wait for interrupt.
* Enable press interrupt and disable release interrupt.
*/
__raw_writew(0x00FF, kpp_dev.base + KPDR);
reg_val = __raw_readw(kpp_dev.base + KPSR);
reg_val |= (KBD_STAT_KPKR | KBD_STAT_KPKD);
reg_val |= KBD_STAT_KRSS | KBD_STAT_KDSC;
__raw_writew(reg_val, kpp_dev.base + KPSR);
reg_val |= KBD_STAT_KDIE;
reg_val &= ~KBD_STAT_KRIE;
__raw_writew(reg_val, kpp_dev.base + KPSR);
/*
* No more keys pressed... make sure unwanted key codes are
* not given upstairs
*/
for (i = 0; i < kpp_dev.kpp_rows; i++) {
memset(press_scancode[i], -1,
sizeof(press_scancode[0][0]) * kpp_dev.kpp_cols);
memset(release_scancode[i], -1,
sizeof(release_scancode[0][0]) *
kpp_dev.kpp_cols);
}
return;
}
/*
* There are still some keys pressed, continue to scan.
* We shall scan again in 10 ms. This has to be tuned according
* to the requirement.
*/
kpp_dev.poll_timer.expires = jiffies + KScanRate;
kpp_dev.poll_timer.function = mxc_kpp_handle_timer;
add_timer(&kpp_dev.poll_timer);
}
/*!
* This function is the keypad Interrupt handler.
* This function checks for keypad status register (KPSR) for key press
* and interrupt. If key press interrupt has occurred, then the key
* press interrupt in the KPSR are disabled.
* It then calls mxc_kpp_scan_matrix to check for any key pressed/released.
* If any key is found to be pressed, then a timer is set to call
* mxc_kpp_scan_matrix function for every 10 ms.
*
* @param irq The Interrupt number
* @param dev_id Driver private data
*
* @result The function returns \b IRQ_RETVAL(1) if interrupt was handled,
* returns \b IRQ_RETVAL(0) if the interrupt was not handled.
* \b IRQ_RETVAL is defined in include/linux/interrupt.h.
*/
static irqreturn_t mxc_kpp_interrupt(int irq, void *dev_id)
{
unsigned short reg_val;
/* Delete the polling timer */
del_timer(&kpp_dev.poll_timer);
reg_val = __raw_readw(kpp_dev.base + KPSR);
/* Check if it is key press interrupt */
if (reg_val & KBD_STAT_KPKD) {
/*
* Disable key press(KDIE status bit) interrupt
*/
reg_val &= ~KBD_STAT_KDIE;
__raw_writew(reg_val, kpp_dev.base + KPSR);
} else {
/* spurious interrupt */
return IRQ_RETVAL(0);
}
/*
* Check if any keys are pressed, if so start polling.
*/
mxc_kpp_handle_timer(0);
return IRQ_RETVAL(1);
}
/*!
* This function is called when the keypad driver is opened.
* Since keypad initialization is done in __init, nothing is done in open.
*
* @param dev Pointer to device inode
*
* @result The function always return 0
*/
static int mxc_kpp_open(struct input_dev *dev)
{
return 0;
}
/*!
* This function is called close the keypad device.
* Nothing is done in this function, since every thing is taken care in
* __exit function.
*
* @param dev Pointer to device inode
*
*/
static void mxc_kpp_close(struct input_dev *dev)
{
}
#ifdef CONFIG_PM
/*!
* This function puts the Keypad controller in low-power mode/state.
* If Keypad is enabled as a wake source(i.e. it can resume the system
* from suspend mode), the Keypad controller doesn't enter low-power state.
*
* @param pdev the device structure used to give information on Keypad
* to suspend
* @param state the power state the device is entering
*
* @return return -1 when the keypad is pressed. Otherwise, return 0
*/
static int mxc_kpp_suspend(struct platform_device *pdev, pm_message_t state)
{
/* When the keypad is still pressed, clean up registers and timers */
if (timer_pending(&kpp_dev.poll_timer))
return -1;
if (device_may_wakeup(&pdev->dev)) {
enable_irq_wake(keypad->irq);
} else {
disable_irq(keypad->irq);
key_pad_enabled = 0;
clk_disable(kpp_clk);
gpio_keypad_inactive();
}
return 0;
}
/*!
* This function brings the Keypad controller back from low-power state.
* If Keypad is enabled as a wake source(i.e. it can resume the system
* from suspend mode), the Keypad controller doesn't enter low-power state.
*
* @param pdev the device structure used to give information on Keypad
* to resume
*
* @return The function always returns 0.
*/
static int mxc_kpp_resume(struct platform_device *pdev)
{
if (device_may_wakeup(&pdev->dev)) {
disable_irq_wake(keypad->irq);
} else {
gpio_keypad_active();
clk_enable(kpp_clk);
key_pad_enabled = 1;
enable_irq(keypad->irq);
}
return 0;
}
#else
#define mxc_kpp_suspend NULL
#define mxc_kpp_resume NULL
#endif /* CONFIG_PM */
/*!
* This function is called to free the allocated memory for local arrays
*/
static void mxc_kpp_free_allocated(void)
{
int i;
if (press_scancode) {
for (i = 0; i < kpp_dev.kpp_rows; i++) {
if (press_scancode[i])
kfree(press_scancode[i]);
}
kfree(press_scancode);
}
if (release_scancode) {
for (i = 0; i < kpp_dev.kpp_rows; i++) {
if (release_scancode[i])
kfree(release_scancode[i]);
}
kfree(release_scancode);
}
if (cur_rcmap)
kfree(cur_rcmap);
if (prev_rcmap)
kfree(prev_rcmap);
if (mxckbd_dev)
input_free_device(mxckbd_dev);
}
/*!
* This function is called during the driver binding process.
*
* @param pdev the device structure used to store device specific
* information that is used by the suspend, resume and remove
* functions.
*
* @return The function returns 0 on successful registration. Otherwise returns
* specific error code.
*/
static int mxc_kpp_probe(struct platform_device *pdev)
{
int i, irq;
int retval;
unsigned int reg_val;
struct resource *res;
keypad = (struct keypad_data *)pdev->dev.platform_data;
kpp_dev.kpp_cols = keypad->colmax;
kpp_dev.kpp_rows = keypad->rowmax;
key_pad_enabled = 0;
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (!res)
return -ENODEV;
kpp_dev.base = ioremap(res->start, res->end - res->start + 1);
if (!kpp_dev.base)
return -ENOMEM;
irq = platform_get_irq(pdev, 0);
keypad->irq = irq;
/* Enable keypad clock */
kpp_clk = clk_get(&pdev->dev, "kpp_clk");
clk_enable(kpp_clk);
/* IOMUX configuration for keypad */
gpio_keypad_active();
/* Configure keypad */
/* Enable number of rows in keypad (KPCR[7:0])
* Configure keypad columns as open-drain (KPCR[15:8])
*
* Configure the rows/cols in KPP
* LSB nibble in KPP is for 8 rows
* MSB nibble in KPP is for 8 cols
*/
reg_val = __raw_readw(kpp_dev.base + KPCR);
reg_val |= (1 << keypad->rowmax) - 1; /* LSB */
reg_val |= ((1 << keypad->colmax) - 1) << 8; /* MSB */
__raw_writew(reg_val, kpp_dev.base + KPCR);
/* Write 0's to KPDR[15:8] */
reg_val = __raw_readw(kpp_dev.base + KPDR);
reg_val &= 0x00ff;
__raw_writew(reg_val, kpp_dev.base + KPDR);
/* Configure columns as output, rows as input (KDDR[15:0]) */
reg_val = __raw_readw(kpp_dev.base + KDDR);
reg_val |= 0xff00;
reg_val &= 0xff00;
__raw_writew(reg_val, kpp_dev.base + KDDR);
reg_val = __raw_readw(kpp_dev.base + KPSR);
reg_val &= ~(KBD_STAT_KPKR | KBD_STAT_KPKD);
reg_val |= KBD_STAT_KPKD;
reg_val |= KBD_STAT_KRSS | KBD_STAT_KDSC;
__raw_writew(reg_val, kpp_dev.base + KPSR);
reg_val |= KBD_STAT_KDIE;
reg_val &= ~KBD_STAT_KRIE;
__raw_writew(reg_val, kpp_dev.base + KPSR);
has_leaning_key = keypad->learning;
mxckpd_keycodes = keypad->matrix;
mxckpd_keycodes_size = keypad->rowmax * keypad->colmax;
if ((keypad->matrix == (void *)0)
|| (mxckpd_keycodes_size == 0)) {
retval = -ENODEV;
goto err1;
}
mxckbd_dev = input_allocate_device();
if (!mxckbd_dev) {
printk(KERN_ERR
"mxckbd_dev: not enough memory for input device\n");
retval = -ENOMEM;
goto err1;
}
mxckbd_dev->keycode = (void *)mxckpd_keycodes;
mxckbd_dev->keycodesize = sizeof(mxckpd_keycodes[0]);
mxckbd_dev->keycodemax = mxckpd_keycodes_size;
mxckbd_dev->name = "mxckpd";
mxckbd_dev->id.bustype = BUS_HOST;
mxckbd_dev->open = mxc_kpp_open;
mxckbd_dev->close = mxc_kpp_close;
retval = input_register_device(mxckbd_dev);
if (retval < 0) {
printk(KERN_ERR
"mxckbd_dev: failed to register input device\n");
goto err2;
}
/* allocate required memory */
press_scancode = kmalloc(kpp_dev.kpp_rows * sizeof(press_scancode[0]),
GFP_KERNEL);
release_scancode =
kmalloc(kpp_dev.kpp_rows * sizeof(release_scancode[0]), GFP_KERNEL);
if (!press_scancode || !release_scancode) {
retval = -ENOMEM;
goto err3;
}
for (i = 0; i < kpp_dev.kpp_rows; i++) {
press_scancode[i] = kmalloc(kpp_dev.kpp_cols
* sizeof(press_scancode[0][0]),
GFP_KERNEL);
release_scancode[i] =
kmalloc(kpp_dev.kpp_cols * sizeof(release_scancode[0][0]),
GFP_KERNEL);
if (!press_scancode[i] || !release_scancode[i]) {
retval = -ENOMEM;
goto err3;
}
}
cur_rcmap =
kmalloc(kpp_dev.kpp_rows * sizeof(cur_rcmap[0]), GFP_KERNEL);
prev_rcmap =
kmalloc(kpp_dev.kpp_rows * sizeof(prev_rcmap[0]), GFP_KERNEL);
if (!cur_rcmap || !prev_rcmap) {
retval = -ENOMEM;
goto err3;
}
__set_bit(EV_KEY, mxckbd_dev->evbit);
for (i = 0; i < mxckpd_keycodes_size; i++)
__set_bit(mxckpd_keycodes[i], mxckbd_dev->keybit);
for (i = 0; i < kpp_dev.kpp_rows; i++) {
memset(press_scancode[i], -1,
sizeof(press_scancode[0][0]) * kpp_dev.kpp_cols);
memset(release_scancode[i], -1,
sizeof(release_scancode[0][0]) * kpp_dev.kpp_cols);
}
memset(cur_rcmap, 0, kpp_dev.kpp_rows * sizeof(cur_rcmap[0]));
memset(prev_rcmap, 0, kpp_dev.kpp_rows * sizeof(prev_rcmap[0]));
key_pad_enabled = 1;
/* Initialize the polling timer */
init_timer(&kpp_dev.poll_timer);
/*
* Request for IRQ number for keypad port. The Interrupt handler
* function (mxc_kpp_interrupt) is called when ever interrupt occurs on
* keypad port.
*/
retval = request_irq(irq, mxc_kpp_interrupt, 0, MOD_NAME, MOD_NAME);
if (retval) {
pr_debug("KPP: request_irq(%d) returned error %d\n",
MXC_INT_KPP, retval);
goto err3;
}
/* By default, devices should wakeup if they can */
/* So keypad is set as "should wakeup" as it can */
device_init_wakeup(&pdev->dev, 1);
return 0;
err3:
mxc_kpp_free_allocated();
err2:
input_free_device(mxckbd_dev);
err1:
free_irq(irq, MOD_NAME);
clk_disable(kpp_clk);
clk_put(kpp_clk);
return retval;
}
/*!
* Dissociates the driver from the kpp device.
*
* @param pdev the device structure used to give information on which SDHC
* to remove
*
* @return The function always returns 0.
*/
static int mxc_kpp_remove(struct platform_device *pdev)
{
unsigned short reg_val;
/*
* Clear the KPKD status flag (write 1 to it) and synchronizer chain.
* Set KDIE control bit, clear KRIE control bit (avoid false release
* events. Disable the keypad GPIO pins.
*/
__raw_writew(0x00, kpp_dev.base + KPCR);
__raw_writew(0x00, kpp_dev.base + KPDR);
__raw_writew(0x00, kpp_dev.base + KDDR);
reg_val = __raw_readw(kpp_dev.base + KPSR);
reg_val |= KBD_STAT_KPKD;
reg_val &= ~KBD_STAT_KRSS;
reg_val |= KBD_STAT_KDIE;
reg_val &= ~KBD_STAT_KRIE;
__raw_writew(reg_val, kpp_dev.base + KPSR);
gpio_keypad_inactive();
clk_disable(kpp_clk);
clk_put(kpp_clk);
KPress = 0;
del_timer(&kpp_dev.poll_timer);
free_irq(keypad->irq, MOD_NAME);
input_unregister_device(mxckbd_dev);
mxc_kpp_free_allocated();
return 0;
}
/*!
* This structure contains pointers to the power management callback functions.
*/
static struct platform_driver mxc_kpd_driver = {
.driver = {
.name = "mxc_keypad",
.bus = &platform_bus_type,
},
.suspend = mxc_kpp_suspend,
.resume = mxc_kpp_resume,
.probe = mxc_kpp_probe,
.remove = mxc_kpp_remove
};
/*!
* This function is called for module initialization.
* It registers keypad char driver and requests for KPP irq number. This
* function does the initialization of the keypad device.
*
* The following steps are used for keypad configuration,\n
* -# Enable number of rows in the keypad control register (KPCR[7:0}).\n
* -# Write 0's to KPDR[15:8]\n
* -# Configure keypad columns as open-drain (KPCR[15:8])\n
* -# Configure columns as output, rows as input (KDDR[15:0])\n
* -# Clear the KPKD status flag (write 1 to it) and synchronizer chain\n
* -# Set KDIE control bit, clear KRIE control bit\n
* In this function the keypad queue initialization is done.
* The keypad IOMUX configuration are done here.*
*
* @return 0 on success and a non-zero value on failure.
*/
static int __init mxc_kpp_init(void)
{
printk(KERN_INFO "MXC keypad loaded\n");
platform_driver_register(&mxc_kpd_driver);
return 0;
}
/*!
* This function is called whenever the module is removed from the kernel. It
* unregisters the keypad driver from kernel and frees the irq number.
* This function puts the keypad to standby mode. The keypad interrupts are
* disabled. It calls gpio_keypad_inactive function to switch gpio
* configuration into default state.
*
*/
static void __exit mxc_kpp_cleanup(void)
{
platform_driver_unregister(&mxc_kpd_driver);
}
module_init(mxc_kpp_init);
module_exit(mxc_kpp_cleanup);
MODULE_AUTHOR("Freescale Semiconductor, Inc.");
MODULE_DESCRIPTION("MXC Keypad Controller Driver");
MODULE_LICENSE("GPL");
|