linux-ezx 2.6.21: update to r2011:

r2011: call send_readurb on bp_rdy signal from BP to keep BP communication active
       add asoc pxa2xx-ssp.c driver from asoc-v0.13rc3
r2010: * pxa-kbd.patch: Fix pxakbd bug: direct keys were not passed to userspace
       * a780-kbd.patch: Cleanup keycodes definition for a780, use unique keycodes so
        to avoid the double event problem occurring when the same keycode is used more
        than once. 
r2003: core:	EZX subsystem
       ezx-phone.c file for each phone
                BP handshake code on a platform_driver (and another .patch)
       pm:      fully functional suspend/resume (except for BP)
                reboot/poweroff
       new:	a780 flip
                e680 lock switch
       bp:	Kconfig entry to disable BP handshake (the watchdog dont start if we dont try to handshake)
       other:	delete obsolete files
r2002: * Implement vibrator handling for a780 using the leds class.
r1999: * Port and readapt ezx-backlight patch. Let's use again the backlight class
         to handle lcd brightness.
r1998: * Port leds patches for A780 and E680 (we still pollute ezx.c for now)

1 files changed, 368 insertions, 0 deletions

diff --git a/packages/linux/linux-ezx-2.6.21/e680-leds.patch b/packages/linux/linux-ezx-2.6.21/e680-leds.patch
new file mode 100644
index 0000000000..37d47f89dc
--- /dev/null
+++ b/packages/linux/linux-ezx-2.6.21/e680-leds.patch
@@ -0,0 +1,368 @@
+
+#
+# Patch managed by http://www.mn-logistik.de/unsupported/pxa250/patcher
+#
+
+Index: linux-2.6.21/drivers/leds/Kconfig
+===================================================================
+--- linux-2.6.21.orig/drivers/leds/Kconfig	2007-05-08 14:31:16.000000000 -0300
++++ linux-2.6.21/drivers/leds/Kconfig	2007-05-08 14:31:17.000000000 -0300
+@@ -111,6 +111,13 @@
+ 	  This option enables support for the LEDs on the
+ 	  Motorola A780 GSM Phone.
+ 
++config LEDS_E680
++	tristate "LED Support for the Motorola E680(i) GSM Phone"
++	depends LEDS_CLASS && PXA_EZX_E680
++	help
++	  This options enables support for the LEDs on the
++	  Motorola E680(i) GSM Phone.
++
+ config LEDS_TRIGGER_TIMER
+ 	tristate "LED Timer Trigger"
+ 	depends on LEDS_TRIGGERS
+Index: linux-2.6.21/drivers/leds/Makefile
+===================================================================
+--- linux-2.6.21.orig/drivers/leds/Makefile	2007-05-08 14:31:16.000000000 -0300
++++ linux-2.6.21/drivers/leds/Makefile	2007-05-08 14:31:17.000000000 -0300
+@@ -17,6 +17,7 @@
+ obj-$(CONFIG_LEDS_H1940)		+= leds-h1940.o
+ obj-$(CONFIG_LEDS_COBALT)		+= leds-cobalt.o
+ obj-$(CONFIG_LEDS_A780)		+= leds-a780.o
++obj-$(CONFIG_LEDS_E680)		+= leds-e680.o
+ 
+ # LED Triggers
+ obj-$(CONFIG_LEDS_TRIGGER_TIMER)	+= ledtrig-timer.o
+Index: linux-2.6.21/drivers/leds/leds-e680.c
+===================================================================
+--- /dev/null	1970-01-01 00:00:00.000000000 +0000
++++ linux-2.6.21/drivers/leds/leds-e680.c	2007-05-08 14:44:39.000000000 -0300
+@@ -0,0 +1,309 @@
++/*
++ * EZX Platform LED Driver for the Motorola E680(i) GSM Phone
++ *
++ * Copyright 2006 Vanille-Media
++ *
++ * Author: Michael Lauer <mickey@Vanille.de>
++ *
++ * Based on the Motorola 2.4 leds-e680.c and leds-corgi.c by Richard Purdie
++ *
++ * This program is free software; you can redistribute it and/or modify
++ * it under the terms of the GNU General Public License version 2 as
++ * published by the Free Software Foundation.
++ *
++ */
++
++#include <linux/delay.h>
++#include <linux/kernel.h>
++#include <linux/init.h>
++#include <linux/platform_device.h>
++#include <linux/leds.h>
++#include <asm/mach-types.h>
++#include <asm/arch/hardware.h>
++#include <asm/arch/pxa-regs.h>
++#include <asm/arch/ezx-pcap.h>
++
++//FIXME move defines to a common header file
++#define IND_CNTL_R_BUL     46
++#define IND_CNTL_G_BUL     47
++#define SSP_PCAP_LED_MASK  0x000fffe0
++#define SSP_PCAP_LED_SHIFT 5
++#define GPIO_TC_MM_EN      99
++
++extern int ezx_pcap_read(u_int8_t, u_int32_t *);
++extern int ezx_pcap_write(u_int8_t, u_int32_t);
++
++static enum led_brightness old_red;
++static enum led_brightness old_green;
++static enum led_brightness old_blue;
++
++typedef struct {
++	unsigned char ind_GPIO_red;    /*Indicator Red control GPIO 46: 0 active, 1 disactive*/
++	unsigned char ind_GPIO_green;  /*Indicator Green control GPIO 47: 0 active, 1 disactive*/
++	unsigned char pcap_LEDR_en;    /*pcap LEDR_EN bit value: 1 =Red LED(&Green) sink circuit enabled*/
++	unsigned char pcap_LEDG_en;    /*pcap LEDG_EN bit value:1 =Green(->Blue)LED sink circuit enabled*/
++	unsigned char pcap_LEDR_CTRL; /* 4bits Sets the timing for the red(&Green) LED sink circuit*/
++	unsigned char pcap_LEDG_CTRL; /* 4bits Sets the timing for the GREEN (->Blue) LED sink circuit*/
++	unsigned char pcap_LEDR_I;   /* 2 bits 00 3mA,01 4mA, 10 5mA, 11 9mA, sets the pulsed current level for LEDR*/
++	unsigned char pcap_LEDG_I;   /* 2 bits 00 3mA,01 4mA, 10 5mA, 11 9mA, sets the pulsed current level for LEDG*/
++	unsigned char pcap_SKIP_on;  /*1=The ON timing sequence defined by LEDx_CTRL is executed on every other cycle*/
++} PCAP2_LED_REGISTER_VALUE;
++
++const PCAP2_LED_REGISTER_VALUE led_register_value[]=
++{
++  /*  on/off pulsepower  timing  intensity */
++	{0x1,0x1, 0x0,0x0, 0x0,0x0, 0x0,0x0,0x0}, /* OFF */
++	{0x0,0x1, 0x1,0x0, 0xc,0x0, 0x1,0x0,0x0}, /* RED */
++	{0x1,0x0, 0x1,0x0, 0xc,0x0, 0x1,0x0,0x0}, /* GREEN */
++	{0x0,0x0, 0x1,0x0, 0xc,0x0, 0x1,0x0,0x0}, /* ORANGE = RED + GREEN */
++	{0x1,0x1, 0x0,0x1, 0x0,0xc, 0x0,0x0,0x0}, /* BLUE */
++	{0x0,0x1, 0x1,0x1, 0xc,0xc, 0x1,0x0,0x0}, /* LIGHT_RED = RED + BLUE */
++	{0x1,0x0, 0x1,0x1, 0xc,0xc, 0x1,0x0,0x0}, /* LIGHT_GREEN = GREEN + BLUE */
++	{0x0,0x0, 0x1,0x1, 0xc,0xc, 0x1,0x0,0x0}, /* WHITE = RED + GREEN + BLUE */
++};
++
++static void e680led_led_set( enum led_brightness red, enum led_brightness green, enum led_brightness blue )
++{
++	unsigned int tempValue = 0;
++	unsigned int value = 0;
++	unsigned int stateIndex = 0;
++	unsigned char gpio_red, gpio_green, ledr_en, ledg_en, ledr_ctrl, ledg_ctrl, ledr_i, ledg_i,skip;
++
++	printk( KERN_DEBUG "e680led_led_set: red=%d, green=%d, blue=%d", red, green, blue );
++	stateIndex = ( ( blue << 2 ) | ( green << 1 ) | ( red ) )   & 0x7;
++	printk( KERN_DEBUG "LED stateIndex is %d", stateIndex );
++	gpio_red   = led_register_value[stateIndex].ind_GPIO_red    & 0x1;
++	gpio_green = led_register_value[stateIndex].ind_GPIO_green  & 0x1;
++	ledr_en    = led_register_value[stateIndex].pcap_LEDR_en    & 0x1;
++	ledg_en    = led_register_value[stateIndex].pcap_LEDG_en    & 0x1;
++	ledr_ctrl  = led_register_value[stateIndex].pcap_LEDR_CTRL  & 0xf;
++	ledg_ctrl  = led_register_value[stateIndex].pcap_LEDG_CTRL  & 0xf;
++	ledr_i     = led_register_value[stateIndex].pcap_LEDR_I     & 0x3;
++	ledg_i     = led_register_value[stateIndex].pcap_LEDG_I     & 0x3;
++	skip       = led_register_value[stateIndex].pcap_SKIP_on    & 0x1;
++
++	/* disable LEDs */
++	if( ezx_pcap_read(SSP_PCAP_ADJ_PERIPH_REGISTER,&tempValue) != SSP_PCAP_SUCCESS )
++	{
++		printk( KERN_WARNING "LED PCAP Read Failed\n" );
++		return;
++	}
++	tempValue &= (~SSP_PCAP_LED_MASK);
++	if( ezx_pcap_write(SSP_PCAP_ADJ_PERIPH_REGISTER,tempValue) != SSP_PCAP_SUCCESS )
++	{
++		printk( KERN_WARNING "LED PCAP Write Failed (Clear Data)\n" );
++		return;
++	}
++
++	/* configure GPIOs as output */
++	pxa_gpio_mode(IND_CNTL_R_BUL | GPIO_OUT);
++	pxa_gpio_mode(IND_CNTL_G_BUL | GPIO_OUT);
++
++	//FIXME: Simplify this logic
++	if ( (gpio_green && gpio_red) )
++	{
++		/*Disable Red & Green signal*/
++		pxa_gpio_set_value(IND_CNTL_R_BUL, 1); /*IND_CNTL_R_BUL Low active*/
++		PGSR(IND_CNTL_R_BUL) = PGSR(IND_CNTL_R_BUL) | GPIO_bit(IND_CNTL_R_BUL);
++
++		pxa_gpio_set_value(IND_CNTL_G_BUL, 0); /*IND_CNTL_G_BUL High active*/
++		PGSR(IND_CNTL_G_BUL) = PGSR(IND_CNTL_G_BUL) & (~GPIO_bit(IND_CNTL_G_BUL));
++
++		printk( KERN_DEBUG "LED GPIO Green & Red Disable\n");
++	} else if ( gpio_green && !gpio_red )
++	{
++		/*Green Disable, Red Enable*/
++		pxa_gpio_set_value(IND_CNTL_R_BUL, 0);
++		PGSR(IND_CNTL_R_BUL) = PGSR(IND_CNTL_R_BUL) & (~GPIO_bit(IND_CNTL_R_BUL));
++
++		pxa_gpio_set_value(IND_CNTL_G_BUL, 0);
++		PGSR(IND_CNTL_G_BUL) = PGSR(IND_CNTL_G_BUL) & (~GPIO_bit(IND_CNTL_G_BUL));
++
++		printk( KERN_DEBUG "LED GPIO Green Disable, Red Enable\n");
++	} else if (gpio_red && !gpio_green )
++	{
++		/*Red Disable, Green Enable*/
++		pxa_gpio_set_value(IND_CNTL_R_BUL, 1);
++		PGSR(IND_CNTL_R_BUL) = PGSR(IND_CNTL_R_BUL) | GPIO_bit(IND_CNTL_R_BUL);
++
++		pxa_gpio_set_value(IND_CNTL_G_BUL, 1);
++		PGSR(IND_CNTL_G_BUL) = PGSR(IND_CNTL_G_BUL) | GPIO_bit(IND_CNTL_G_BUL);
++		printk( KERN_DEBUG "LED GPIO Red Disable, Green Enable");
++	}else
++	{
++		/*Red & Green enable*/
++		pxa_gpio_set_value(IND_CNTL_R_BUL, 0);
++		PGSR(IND_CNTL_R_BUL) = PGSR(IND_CNTL_R_BUL) & (~GPIO_bit(IND_CNTL_R_BUL));
++
++		pxa_gpio_set_value(IND_CNTL_G_BUL, 1);
++		PGSR(IND_CNTL_G_BUL) = PGSR(IND_CNTL_G_BUL) | GPIO_bit(IND_CNTL_G_BUL);
++		printk( KERN_DEBUG "LED GPIO Red & Green Enable\n");
++	}
++
++	/* Write PCAP LED Peripheral Control Register*/
++	value = ( ledr_en | (ledg_en <<1) | (ledr_ctrl <<2) | (ledg_ctrl <<6) |
++		(ledr_i << 10) | (ledg_i <<12) | (skip <<14) ) & 0x7fff;
++	tempValue |= (value <<SSP_PCAP_LED_SHIFT);
++
++	if ( ezx_pcap_write(SSP_PCAP_ADJ_PERIPH_REGISTER,tempValue) == SSP_PCAP_SUCCESS )
++	{
++		printk( KERN_DEBUG "LED PCAP Write Success (0x%x :0x%x)\n",tempValue,value);
++		old_red = red;
++		old_green = green;
++		old_blue = blue;
++		return;
++	} else {
++		printk( KERN_DEBUG "LED PCAP Write Failed (State Change)\n");
++		return;
++	}
++}
++
++static void e680led_red_set(struct led_classdev *led_cdev, enum led_brightness value)
++{
++	printk( KERN_DEBUG "e680led_red_set: %d\n", value );
++	e680led_led_set( 1 && value, old_green, old_blue );
++}
++
++static void e680led_green_set(struct led_classdev *led_cdev, enum led_brightness value)
++{
++	printk( KERN_DEBUG "e680led_green_set: %d\n", value );
++	e680led_led_set( old_red, 1 && value, old_blue );
++}
++
++static void e680led_blue_set(struct led_classdev *led_cdev, enum led_brightness value)
++{
++	printk( KERN_DEBUG "e680led_blue_set: %d\n", value );
++	e680led_led_set( old_red, old_green, 1 && value );
++}
++
++static void e680led_keypad_set(struct led_classdev *led_cdev, enum led_brightness value)
++{
++	/* this is not working yet, as there is something else missing */
++#if 0
++	printk( KERN_DEBUG "e680led_keypad_set: %d\n", value );
++
++	pxa_gpio_mode(GPIO_TC_MM_EN);
++	GPDR(GPIO_TC_MM_EN)   |= GPIO_bit(GPIO_TC_MM_EN);
++	GPSR(GPIO_TC_MM_EN)   = GPIO_bit(GPIO_TC_MM_EN);
++
++	udelay( 100 );
++
++    if ( value ) {
++		GPCR(GPIO_TC_MM_EN)   = GPIO_bit(GPIO_TC_MM_EN);
++		PGSR3 &= ~GPIO_bit(GPIO_TC_MM_EN);
++    } else {
++		GPSR(GPIO_TC_MM_EN)   = GPIO_bit(GPIO_TC_MM_EN);
++		PGSR3 |= GPIO_bit(GPIO_TC_MM_EN);
++    }
++#endif
++}
++
++static struct led_classdev e680_red_led = {
++	.name			= "e680:red",
++	.default_trigger	= "none",
++	.brightness_set		= e680led_red_set,
++};
++
++static struct led_classdev e680_green_led = {
++	.name			= "e680:green",
++	.default_trigger	= "none",
++	.brightness_set		= e680led_green_set,
++};
++
++static struct led_classdev e680_blue_led = {
++	.name			= "e680:blue",
++	.default_trigger	= "none",
++	.brightness_set		= e680led_blue_set,
++};
++
++static struct led_classdev e680_keypad_led = {
++	.name			= "e680:keypad",
++	.default_trigger	= "none",
++	.brightness_set		= e680led_keypad_set,
++};
++
++#ifdef CONFIG_PM
++static int e680led_suspend(struct platform_device *dev, pm_message_t state)
++{
++	led_classdev_suspend(&e680_red_led);
++	led_classdev_suspend(&e680_green_led);
++	led_classdev_suspend(&e680_blue_led);
++	led_classdev_suspend(&e680_keypad_led);
++	return 0;
++}
++
++static int e680led_resume(struct platform_device *dev)
++{
++	led_classdev_resume(&e680_red_led);
++	led_classdev_resume(&e680_green_led);
++	led_classdev_resume(&e680_blue_led);
++	led_classdev_resume(&e680_keypad_led);
++	return 0;
++}
++#endif
++
++static int e680led_probe(struct platform_device *pdev)
++{
++	int ret;
++
++	ret = led_classdev_register(&pdev->dev, &e680_red_led);
++	if (ret < 0)
++		return ret;
++
++	ret = led_classdev_register(&pdev->dev, &e680_green_led);
++	if (ret < 0)
++		led_classdev_unregister(&e680_red_led);
++
++	ret = led_classdev_register(&pdev->dev, &e680_blue_led);
++	if (ret < 0) {
++		led_classdev_unregister(&e680_red_led);
++		led_classdev_unregister(&e680_green_led);
++	}
++
++	ret = led_classdev_register(&pdev->dev, &e680_keypad_led);
++	if (ret < 0) {
++		led_classdev_unregister(&e680_red_led);
++		led_classdev_unregister(&e680_green_led);
++		led_classdev_unregister(&e680_blue_led);
++	}
++	return ret;
++}
++
++static int e680led_remove(struct platform_device *pdev)
++{
++	led_classdev_unregister(&e680_red_led);
++	led_classdev_unregister(&e680_green_led);
++	led_classdev_unregister(&e680_blue_led);
++	led_classdev_unregister(&e680_keypad_led);
++	return 0;
++}
++
++static struct platform_driver e680led_driver = {
++	.probe		= e680led_probe,
++	.remove		= e680led_remove,
++#ifdef CONFIG_PM
++	.suspend	= e680led_suspend,
++	.resume		= e680led_resume,
++#endif
++	.driver		= {
++		.name		= "e680-led",
++	},
++};
++
++static int __init e680led_init(void)
++{
++	return platform_driver_register(&e680led_driver);
++}
++
++static void __exit e680led_exit(void)
++{
++	e680led_led_set( 0, 0, 0 );
++	platform_driver_unregister(&e680led_driver);
++}
++
++module_init(e680led_init);
++module_exit(e680led_exit);
++
++MODULE_AUTHOR("Michael Lauer <mickey@Vanille.de>");
++MODULE_DESCRIPTION("Motorola E680 LED driver");
++MODULE_LICENSE("GPL");
+Index: linux-2.6.21/arch/arm/mach-pxa/ezx-e680.c
+===================================================================
+--- linux-2.6.21.orig/arch/arm/mach-pxa/ezx-e680.c	2007-05-08 14:23:29.000000000 -0300
++++ linux-2.6.21/arch/arm/mach-pxa/ezx-e680.c	2007-05-08 14:31:17.000000000 -0300
+@@ -221,8 +221,14 @@
+        },
+ };
+ 
++static struct platform_device e680led_device = {
++	.name		= "e680-led",
++	.id		= -1,
++};
++
+ static struct platform_device *devices[] __initdata = {
+ 	&e680locksw_device,
++	&e680led_device,
+ };
+ 
+ static void __init e680_init(void)