+diff -urN linux.old/drivers/char/avalanche_led/gpio.c linux.dev/drivers/char/avalanche_led/gpio.c
+--- linux.old/drivers/char/avalanche_led/gpio.c 1970-01-01 01:00:00.000000000 +0100
++++ linux.dev/drivers/char/avalanche_led/gpio.c 2005-07-22 06:52:42.973338640 +0200
+@@ -0,0 +1,382 @@
++#include <linux/kernel.h>
++#include <asm/uaccess.h>
++#include <linux/spinlock.h>
++#include <linux/proc_fs.h>
++#include <linux/fs.h>
++#include <linux/timer.h>
++#include <linux/module.h>
++
++#include <asm/ar7/tnetd73xx_err.h>
++#include <asm/ar7/tnetd73xx_misc.h>
++#include <asm/ar7/ledapp.h>
++
++#define TRUE 1
++#define FALSE 0
++
++#if defined CONFIG_AR7WRD || defined CONFIG_AR7RD
++
++#define AR7_RESET_FILE "led_mod/ar7reset"
++#define AR7_VERSION_FILE "led_mod/hardware_version"
++#define AR7_RESET_GPIO 11
++#define RESET_POLL_TIME 1
++#define RESET_HOLD_TIME 4
++#define NO_OF_LEDS
++
++static struct proc_dir_entry *reset_file;
++static int res_state = 0;
++static int count;
++static struct timer_list *pTimer = NULL;
++static ssize_t proc_read_reset_fops(struct file *filp,
++ char *buf,size_t count , loff_t *offp);
++
++static ssize_t proc_read_hwversion_fops(struct file *filp,
++ char *buf,size_t count , loff_t *offp);
++
++struct file_operations reset_fops = {
++ read: proc_read_reset_fops
++ };
++struct file_operations hardware_version_fops = {
++ read: proc_read_hwversion_fops
++ };
++#endif
++
++static spinlock_t device_lock;
++led_reg_t temp[15];
++
++static void gpio_led_on( unsigned long param )
++{
++ unsigned int flags;
++
++ spin_lock_irqsave(&device_lock, flags);
++
++ tnetd73xx_gpio_out(param,FALSE);
++ spin_unlock_irqrestore(&device_lock, flags);
++}
++
++static void gpio_led_off ( unsigned long param )
++{
++ unsigned int flags = 0x00;
++
++ spin_lock_irqsave(&device_lock, flags);
++
++ tnetd73xx_gpio_out(param,TRUE);
++ spin_unlock_irqrestore(&device_lock, flags);
++}
++
++static void gpio_led_init( unsigned long param)
++{
++ tnetd73xx_gpio_ctrl(param,GPIO_PIN,GPIO_OUTPUT_PIN);
++}
++
++static void board_gpio_reset(void)
++{
++ /* Initialize the link mask */
++ device_lock = SPIN_LOCK_UNLOCKED;
++ return;
++}
++
++#if defined CONFIG_AR7WRD || defined CONFIG_AR7RD
++
++static ssize_t proc_read_hwversion_fops(struct file *filp, char *buf,
++ size_t count, loff_t *offp)
++{
++ char line[8];
++ int len = 0;
++ if( *offp != 0 )
++ return 0;
++
++ len = sprintf(line, "%d%d.%d%d%d%d\n", tnetd73xx_gpio_in(20),
++ tnetd73xx_gpio_in(21), tnetd73xx_gpio_in(22),
++ tnetd73xx_gpio_in(23), tnetd73xx_gpio_in(24),
++ tnetd73xx_gpio_in(25));
++
++ copy_to_user(buf, line, len);
++ *offp = len;
++ return len;
++}
++
++static ssize_t proc_read_reset_fops(struct file *filp,
++ char *buf,size_t count , loff_t *offp)
++{
++ char * pdata = NULL;
++ char line[3];
++ int len = 0;
++ if( *offp != 0 )
++ return 0;
++
++ pdata = buf;
++ len = sprintf(line,"%d\n", res_state );
++//wwzh
++// res_state = 0;
++ copy_to_user(buf,line,len );
++ *offp = len;
++ return len;
++}
++
++static void reset_timer_func(unsigned long data)
++{
++//wwzh
++#if 0
++ count = (tnetd73xx_gpio_in(AR7_RESET_GPIO) == 0) ? count + 1: 0;
++ if( count >= RESET_HOLD_TIME/RESET_POLL_TIME )
++#endif
++ if (tnetd73xx_gpio_in(AR7_RESET_GPIO) == 0)
++ res_state = 1;
++ else
++ res_state = 0;
++ pTimer->expires = jiffies + HZ*RESET_POLL_TIME;
++ add_timer (pTimer);
++ return;
++}
++
++static void hardware_version_init(void)
++{
++ static struct proc_dir_entry *hardware_version_file;
++ hardware_version_file = create_proc_entry(AR7_VERSION_FILE, 0777, NULL);
++ if(hardware_version_file == NULL)
++ return;
++
++ hardware_version_file->owner = THIS_MODULE;
++ hardware_version_file->proc_fops = &hardware_version_fops;
++
++ tnetd73xx_gpio_ctrl(20,GPIO_PIN,GPIO_INPUT_PIN);
++ tnetd73xx_gpio_ctrl(21,GPIO_PIN,GPIO_INPUT_PIN);
++ tnetd73xx_gpio_ctrl(22,GPIO_PIN,GPIO_INPUT_PIN);
++ tnetd73xx_gpio_ctrl(23,GPIO_PIN,GPIO_INPUT_PIN);
++ tnetd73xx_gpio_ctrl(24,GPIO_PIN,GPIO_INPUT_PIN);
++ tnetd73xx_gpio_ctrl(25,GPIO_PIN,GPIO_INPUT_PIN);
++
++ return;
++}
++
++static void reset_init(void)
++{
++ /* Create board reset proc file */
++ reset_file = create_proc_entry( AR7_RESET_FILE, 0777, NULL);
++ if( reset_file == NULL)
++ goto reset_file;
++ reset_file->owner = THIS_MODULE;
++ reset_file->proc_fops = &reset_fops;
++
++ /* Initialise GPIO 11 for input */
++ tnetd73xx_gpio_ctrl(AR7_RESET_GPIO,GPIO_PIN,GPIO_INPUT_PIN);
++
++ /* Create a timer which fires every seconds */
++ pTimer = kmalloc(sizeof(struct timer_list),GFP_KERNEL);
++ init_timer( pTimer );
++ pTimer->function = reset_timer_func;
++ pTimer->data = 0;
++ /* Start the timer */
++ reset_timer_func(0);
++ return ;
++
++ reset_file:
++ remove_proc_entry("AR7_RESET_FILE",NULL);
++ return;
++}
++#endif
++/*************wwzh****************/
++#if 1
++extern unsigned int sys_mod_state;
++extern unsigned int wan_mod_state;
++extern unsigned int wlan_mod_state;
++void sys_led_init(void)
++{
++ tnetd73xx_gpio_ctrl(4, GPIO_PIN, GPIO_OUTPUT_PIN);
++ tnetd73xx_gpio_ctrl(5, GPIO_PIN, GPIO_OUTPUT_PIN);
++ tnetd73xx_gpio_ctrl(8, GPIO_PIN, GPIO_OUTPUT_PIN);
++
++ tnetd73xx_gpio_out(4, FALSE);
++ tnetd73xx_gpio_out(5, TRUE);
++ tnetd73xx_gpio_out(8, TRUE);
++
++
++ sys_mod_state = 2;
++
++}
++void wan_led_init(void)
++{
++
++ tnetd73xx_gpio_ctrl(2, GPIO_PIN, GPIO_OUTPUT_PIN);
++ tnetd73xx_gpio_ctrl(3, GPIO_PIN, GPIO_OUTPUT_PIN);
++
++ tnetd73xx_gpio_out(2, FALSE);
++ tnetd73xx_gpio_out(3, FALSE);
++
++ wan_mod_state = 1;
++}
++//wwzh wireless
++#if 0
++void wlan_led_init(void)
++{
++ //unsigned long i = 0;
++ tnetd73xx_gpio_ctrl(12, GPIO_PIN, GPIO_OUTPUT_PIN);
++ tnetd73xx_gpio_ctrl(13, GPIO_PIN, GPIO_OUTPUT_PIN);
++
++ tnetd73xx_gpio_out(12, FALSE);
++ tnetd73xx_gpio_out(13, TRUE);
++ //for (i = 0; i < 0x20000000; i++);
++ wlan_mod_state = 1;
++}
++#endif
++
++#endif
++/*************end ****************/
++
++void board_gpio_init(void)
++{
++
++ board_gpio_reset();
++/**************wwzh*************/
++ sys_led_init();
++ wan_led_init();
++
++ //junzhao 2004.3.15
++ hardware_version_init();
++
++ //wlan_led_init();
++
++ /* Register Device MAX_LED_ID + 1 for reset to factory default */
++ temp[0].param = 0;
++ temp[0].init = reset_init;
++ temp[0].onfunc = 0;
++ temp[0].offfunc = 0;
++ register_led_drv( MAX_LED_ID + 1 , &temp[0]);
++//wwzh for wireless led
++#if 1
++ /* Register led 12 WiFi 6 */
++ temp[1].param = 6;
++ temp[1].init = gpio_led_init;
++ temp[1].onfunc = gpio_led_on;
++ temp[1].offfunc = gpio_led_off;
++ register_led_drv( 12 , &temp[1]);
++
++#endif
++
++#if 0
++/**************end ************/
++#if defined(CONFIG_AR5D01)
++ /* Register led 1 GPIO0 */
++ temp[0].param = GPIO_0;
++ temp[0].init = gpio_led_init;
++ temp[0].onfunc = gpio_led_on;
++ temp[0].offfunc = gpio_led_off;
++ register_led_drv( 1 , &temp[0]);
++
++ /* Register led 2 EINT1 */
++ temp[1].param = EINT_1;
++ temp[1].init = gpio_led_init;
++ temp[1].onfunc = gpio_led_on;
++ temp[1].offfunc = gpio_led_off;
++ register_led_drv( 2 , &temp[1]);
++
++ /* Register led 5 EINT1 */
++ temp[2].param = GPIO_1;
++ temp[2].init = gpio_led_init;
++ temp[2].onfunc = gpio_led_on;
++ temp[2].offfunc = gpio_led_off;
++ register_led_drv( 5 , &temp[2]);
++#endif
++
++#if defined(CONFIG_AR5W01)
++ /* Register led 5 GPIO_1 */
++ temp[0].param = GPIO_1;
++ temp[0].init = gpio_led_init;
++ temp[0].onfunc = gpio_led_on;
++ temp[0].offfunc = gpio_led_off;
++ register_led_drv( 5 , &temp[0]);
++
++ /* Register led 7 GPIO_0 */
++ temp[1].param = GPIO_0;
++ temp[1].init = gpio_led_init;
++ temp[1].onfunc = gpio_led_on;
++ temp[1].offfunc = gpio_led_off;
++ register_led_drv( 7 , &temp[1]);
++#endif
++
++//wwzh #if defined(CONFIG_AR7RD)
++#if defined CONFIG_AR7WRD || defined CONFIG_AR7RD
++ /* Register led 5 Green PPPOE GPIO 13 */
++ temp[0].param = 13;
++ temp[0].init = gpio_led_init;
++ temp[0].onfunc = gpio_led_on;
++ temp[0].offfunc = gpio_led_off;
++ register_led_drv( 5 , &temp[0]);
++
++ /* Register led 7 Green USB GPIO 12 */
++ temp[1].param = 12;
++ temp[1].init = gpio_led_init;
++ temp[1].onfunc = gpio_led_on;
++ temp[1].offfunc = gpio_led_off;
++ register_led_drv( 7 , &temp[1]);
++
++ /* Register Device MAX_LED_ID + 1 for reset to factory default */
++ temp[2].param = 0;
++ temp[2].init = reset_init;
++ temp[2].onfunc = 0;
++ temp[2].offfunc = 0;
++ register_led_drv( MAX_LED_ID + 1 , &temp[2]);
++
++ /* Register led 8 RED DSL GPIO 10 */
++ temp[3].param = 10;
++ temp[3].init = gpio_led_init;
++ temp[3].onfunc = gpio_led_on;
++ temp[3].offfunc = gpio_led_off;
++ register_led_drv( 8 , &temp[3]);
++
++ /* Register led 9 RED PPPoE down GPIO 9 */
++ temp[4].param = 9;
++ temp[4].init = gpio_led_init;
++ temp[4].onfunc = gpio_led_on;
++ temp[4].offfunc = gpio_led_off;
++ register_led_drv( 9 , &temp[4]);
++
++ /* Register led 10 DSL down GPIO 8 */
++ temp[5].param = 8;
++ temp[5].init = gpio_led_init;
++ temp[5].onfunc = gpio_led_on;
++ temp[5].offfunc = gpio_led_off;
++ register_led_drv( 10 , &temp[5]);
++
++ /* Register led 11 Power GPIO 7 */
++ temp[6].param = 7;
++ temp[6].init = gpio_led_init;
++ temp[6].onfunc = gpio_led_on;
++ temp[6].offfunc = gpio_led_off;
++ register_led_drv( 11 , &temp[6]);
++
++ /* Register led 12 WiFi 6 */
++ temp[7].param = 6;
++ temp[7].init = gpio_led_init;
++ temp[7].onfunc = gpio_led_on;
++ temp[7].offfunc = gpio_led_off;
++ register_led_drv( 12 , &temp[7]);
++
++ /* Register led 13 ELINK(AA1313) GPIO 15 */
++ temp[8].param = 15;
++ temp[8].init = gpio_led_init;
++ temp[8].onfunc = gpio_led_on;
++ temp[8].offfunc = gpio_led_off;
++ register_led_drv( 13 , &temp[8]);
++
++ /* Register led 14 EACT(Y13) GPIO 16 */
++ temp[9].param = 16;
++ temp[9].init = gpio_led_init;
++ temp[9].onfunc = gpio_led_on;
++ temp[9].offfunc = gpio_led_off;
++ register_led_drv( 14 , &temp[9]);
++
++#endif
++/**************wwzh**************/
++#endif
++/**************end **************/
++ return;
++}
++
++
++
++
++
++
++
++
diff -urN linux.old/drivers/char/avalanche_led/ledmod.c linux.dev/drivers/char/avalanche_led/ledmod.c
--- linux.old/drivers/char/avalanche_led/ledmod.c 1970-01-01 01:00:00.000000000 +0100
-+++ linux.dev/drivers/char/avalanche_led/ledmod.c 2005-07-11 03:16:48.247012224 +0200
-@@ -0,0 +1,719 @@
++++ linux.dev/drivers/char/avalanche_led/ledmod.c 2005-07-22 06:52:42.975338336 +0200
+@@ -0,0 +1,1116 @@
+#include <linux/config.h>
+#include <linux/init.h>
+#include <linux/kernel.h>
+#define LED_BLINK_UP 5
+#define LED_BLINK_DOWN 6
+
-+typedef struct state_entry {
-+ unsigned char mode;
-+ unsigned char led;
-+ void (*handler) (struct state_entry * pState);
-+ unsigned long param;
-+} state_entry_t;
++extern void avalanche_leds_init(void);
++
++/***********wwzh**************/
++unsigned int sys_mod_state;
++unsigned int wan_mod_state;
++unsigned int wlan_mod_state;
+
-+typedef struct mod_entry {
-+ state_entry_t *states[MAX_STATE_ID];
-+} mod_entry_t;
++struct timer_list *pWanTimer = NULL;
++struct timer_list *pWlanTimer = NULL;
++/***********end **************/
++
++typedef struct state_entry{
++ unsigned char mode;
++ unsigned char led;
++ void (*handler)(struct state_entry *pState);
++ unsigned long param;
++}state_entry_t;
++
++typedef struct mod_entry{
++ state_entry_t *states[MAX_STATE_ID];
++}mod_entry_t;
+
+static mod_entry_t *modArr[MAX_MOD_ID];
-+static struct proc_dir_entry *led_proc_dir, *led_file;
++static struct proc_dir_entry *led_proc_dir,*led_file;
+
+/* index of the array is the led number HARDWARE SPECIFIC*/
-+typedef struct led_data {
++typedef struct led_data{
+ led_reg_t *led;
-+ int state;
++ int state;
+ struct timer_list *pTimer;
+ unsigned char timer_running;
-+ unsigned long param;
-+} led_data_t;
++ unsigned long param;
++}led_data_t;
+
+led_data_t led_arr[MAX_LED_ID + 1];
+/*!!! The last device is actually being used for ar7 reset to factory default */
-+#if 1
-+/* Ron add for adsl LED blink */
-+#define GPIO_ADSL_ACT (1<<6)
-+#define GPIO_ADSL_DOWN (1<<8)
-+#define BLINK_FAST 5*HZ/100
-+#define BLINK_SLOW 15*HZ/100
-+static struct timer_list my_led_timer;
-+static int my_blink_count = 0;
-+static int my_mode = 1;
-+void led_operation(int mod, int state);
-+
-+static void my_led_on(unsigned long gpio, int logic)
-+{
-+ if (logic > 0)
-+ GPIO_DATA_OUTPUT |= gpio;
-+ else
-+ GPIO_DATA_OUTPUT &= ~gpio;
-+
-+}
-+static void my_led_off(unsigned long gpio, int logic)
-+{
-+ if (logic > 0)
-+ GPIO_DATA_OUTPUT &= ~gpio;
-+ else
-+ GPIO_DATA_OUTPUT |= gpio;
-+
-+}
+
-+static void my_led_init(unsigned long gpio, int init, int logic)
-+{
-+ GPIO_DATA_ENABLE |= gpio;
-+ GPIO_DATA_DIR &= ~gpio;
-+ if (init)
-+ my_led_on(gpio, logic);
-+ else
-+ my_led_off(gpio, logic);
-+}
+
-+static void my_led_blink_timer(unsigned long data)
-+{
-+ unsigned long gpio = GPIO_ADSL_ACT;
-+ unsigned int speed = BLINK_FAST;
-+ if (my_mode == 2) {
-+ gpio = GPIO_ADSL_DOWN;
-+ speed = BLINK_SLOW;
-+ }
-+ if (my_blink_count) {
-+ if (GPIO_DATA_OUTPUT & gpio) {
-+ GPIO_DATA_OUTPUT &= ~gpio;
-+ if (my_mode != 2)
-+ my_blink_count = 0;
-+ } else {
-+ GPIO_DATA_OUTPUT |= gpio;
-+ }
-+ }
-+ my_led_timer.expires = jiffies + speed;
-+ add_timer(&my_led_timer);
-+}
-+
-+/* Ron add for ADSL led blink */
-+#endif
-+static spinlock_t config_lock;
++static spinlock_t config_lock;
+
-+static void board_led_link_up(state_entry_t * pState);
-+static void board_led_link_down(state_entry_t * pState);
-+static void board_led_activity_on(state_entry_t * pState);
-+static void board_led_activity_off(state_entry_t * pState);
++static void board_led_link_up( state_entry_t *pState );
++static void board_led_link_down( state_entry_t *pState );
++static void board_led_activity_on( state_entry_t *pState );
++static void board_led_activity_off( state_entry_t *pState );
+static void led_timer_func(unsigned long data);
+
-+static ssize_t proc_read_led_fops(struct file *filp, char *buf, size_t count, loff_t * offp);
-+static ssize_t proc_write_led_fops(struct file *filp, const char *buffer, size_t count, loff_t * offp);
-+static int config_led(unsigned long y);
++extern void board_gpio_init(void);
++extern void uart_led_init(void);
++
++static ssize_t proc_read_led_fops(struct file *filp,
++ char *buf,size_t count , loff_t *offp);
++static ssize_t proc_write_led_fops(struct file *filp,const char *buffer,
++ size_t count , loff_t *offp);
++static int config_led( unsigned long y);
+
+struct file_operations led_fops = {
-+ read:proc_read_led_fops,
-+ write:proc_write_led_fops,
-+};
++ read: proc_read_led_fops,
++ write: proc_write_led_fops,
++ };
+
-+static int led_atoi(char *name)
++static int led_atoi( char *name)
+{
+ int val = 0;
-+ for (;; name++) {
-+ switch (*name) {
-+ case '0'...'9':
-+ val = val * 10 + (*name - '0');
-+ break;
-+ default:
-+ return val;
++ for(;;name++)
++ {
++ switch(*name)
++ {
++ case '0'...'9':
++ val = val*10+(*name - '0');
++ break;
++ default:
++ return val;
+ }
+ }
+}
+
+static int free_memory(void)
+{
-+ int i, j;
-+
-+ for (i = 0; i < MAX_MOD_ID; i++) {
-+ if (modArr[i] != NULL) {
-+ for (j = 0; j < MAX_STATE_ID; j++) {
-+ if (modArr[i]->states[j] != NULL)
-+ kfree(modArr[i]->states[j]);
++ int i, j;
++
++ for( i = 0; i < MAX_MOD_ID ; i++)
++ {
++ if( modArr[i] != NULL )
++ {
++ for( j = 0; j < MAX_STATE_ID ; j++ )
++ {
++ if( modArr[i]->states[j] != NULL )
++ kfree( modArr[i]->states[j]);
+ }
+ kfree(modArr[i]);
-+ modArr[i] = NULL;
++ modArr[i] = NULL;
+ }
+ }
-+ return 0;
++ return 0;
+}
+
-+static int led_on(state_entry_t * pState)
++static int led_on( state_entry_t *pState )
+{
-+ if (led_arr[pState->led].led == NULL)
++ if( led_arr[pState->led].led == NULL)
+ return -1;
-+ led_arr[pState->led].led->onfunc(led_arr[pState->led].led->param);
-+ return 0;
++ led_arr[pState->led].led->onfunc( led_arr[pState->led].led->param);
++ return 0;
+}
+
-+static int led_off(state_entry_t * pState)
++static int led_off( state_entry_t *pState )
+{
-+ if (led_arr[pState->led].led == NULL)
++ if( led_arr[pState->led].led == NULL)
+ return -1;
-+ led_arr[pState->led].led->offfunc(led_arr[pState->led].led->param);
-+ return 0;
++ led_arr[pState->led].led->offfunc( led_arr[pState->led].led->param);
++ return 0;
+}
+
-+static void board_led_link_up(state_entry_t * pState)
++static void board_led_link_up( state_entry_t *pState )
+{
-+ led_arr[pState->led].state = LED_ON;
-+ if (led_arr[pState->led].timer_running == 0)
-+ led_on(pState);
-+ return;
++ led_arr[pState->led].state = LED_ON;
++ if( led_arr[pState->led].timer_running == 0 )
++ led_on(pState);
++ return;
+}
+
-+static void board_led_link_down(state_entry_t * pState)
++static void board_led_link_down( state_entry_t *pState )
+{
+ led_arr[pState->led].state = LED_OFF;
-+ if (led_arr[pState->led].timer_running == 0)
-+ led_off(pState);
-+ return;
++ if( led_arr[pState->led].timer_running == 0 )
++ led_off(pState);
++ return;
+}
+
-+static void add_led_timer(state_entry_t * pState)
++static void add_led_timer(state_entry_t *pState)
+{
-+ led_arr[pState->led].pTimer->expires =
-+ jiffies + HZ * (pState->param) / 1000;
-+ led_arr[pState->led].param = pState->param;
-+ led_arr[pState->led].pTimer->data = pState;
-+ add_timer(led_arr[pState->led].pTimer);
++ led_arr[pState->led].pTimer->expires = jiffies + HZ*(pState->param)/1000;
++ led_arr[pState->led].param = pState->param;
++ led_arr[pState->led].pTimer->data = pState;
++ add_timer (led_arr[pState->led].pTimer);
+}
+
-+static void board_led_activity_on(state_entry_t * pState)
++static void board_led_activity_on(state_entry_t *pState)
+{
-+ if (led_arr[pState->led].timer_running == 0) {
++ if(led_arr[pState->led].timer_running == 0)
++ {
+ led_on(pState);
+ add_led_timer(pState);
-+ led_arr[pState->led].timer_running = 1;
-+ led_arr[pState->led].state = LED_BLINK_UP;
-+ } else if (led_arr[pState->led].timer_running > 0xF0) {
-+ led_arr[pState->led].state = LED_BLINK_UP;
-+ led_arr[pState->led].pTimer->expires =
-+ jiffies + HZ * (pState->param) / 1000;
-+ led_arr[pState->led].param = pState->param;
-+ led_arr[pState->led].pTimer->data = pState;
++ led_arr[pState->led].timer_running = 1;
++ led_arr[pState->led].state = LED_BLINK_UP;
++ }
++ else if( led_arr[pState->led].timer_running > 0xF0)
++ {
++ led_arr[pState->led].state = LED_BLINK_UP;
++ led_arr[pState->led].pTimer->expires = jiffies + HZ*(pState->param)/1000;
++ led_arr[pState->led].param = pState->param;
++ led_arr[pState->led].pTimer->data = pState;
+ }
+ return;
+}
+
-+static void board_led_activity_off(state_entry_t * pState)
++static void board_led_activity_off(state_entry_t *pState)
+{
-+ if (led_arr[pState->led].timer_running == 0) {
++ if(led_arr[pState->led].timer_running == 0)
++ {
+ led_off(pState);
+ add_led_timer(pState);
-+ led_arr[pState->led].timer_running = 1;
-+ led_arr[pState->led].state = LED_BLINK_UP;
-+ } else if (led_arr[pState->led].timer_running > 0xF0) {
-+ led_arr[pState->led].state = LED_BLINK_UP;
-+ led_arr[pState->led].pTimer->expires =
-+ jiffies + HZ * (pState->param) / 1000;
-+ led_arr[pState->led].param = pState->param;
-+ led_arr[pState->led].pTimer->data = pState;
++ led_arr[pState->led].timer_running = 1;
++ led_arr[pState->led].state = LED_BLINK_UP;
++ }
++ else if( led_arr[pState->led].timer_running > 0xF0)
++ {
++ led_arr[pState->led].state = LED_BLINK_UP;
++ led_arr[pState->led].pTimer->expires = jiffies + HZ*(pState->param)/1000;
++ led_arr[pState->led].param = pState->param;
++ led_arr[pState->led].pTimer->data = pState;
+ }
+ return;
+}
+
-+static void board_led_link_flash(state_entry_t * pState)
++static void board_led_link_flash(state_entry_t *pState)
+{
-+ if (led_on(pState))
++ if(led_on(pState))
+ return;
-+ if (led_arr[pState->led].timer_running == 0)
++ if(led_arr[pState->led].timer_running == 0)
+ add_led_timer(pState);
+ else
-+ led_arr[pState->led].param = pState->param;
-+ led_arr[pState->led].timer_running = 0xFF;
++ led_arr[pState->led].param = pState->param;
++ led_arr[pState->led].timer_running = 0xFF;
+ led_arr[pState->led].state = LED_FLASH;
+ return;
+}
+static void led_timer_func(unsigned long data)
+{
+ state_entry_t *pState = NULL;
-+ mod_entry_t *pMod = NULL;
++ mod_entry_t *pMod = NULL;
+ unsigned int flags;
+
+ spin_lock_irqsave(&config_lock, flags);
+
-+ pState = (state_entry_t *) data;
++ pState = (state_entry_t *)data;
+
-+ if (led_arr[pState->led].state == LED_BLINK_DOWN) {
++ if( led_arr[pState->led].state == LED_BLINK_DOWN )
++ {
+ led_arr[pState->led].timer_running = 0;
-+ if (pState->mode == 2)
++ if( pState->mode == 2 )
+ led_arr[pState->led].state = LED_OFF;
+ else
+ led_arr[pState->led].state = LED_ON;
-+ } else if (led_arr[pState->led].state == LED_BLINK_UP) {
-+ led_arr[pState->led].pTimer->expires =
-+ jiffies + HZ * (led_arr[pState->led].param) / 1000;
-+ led_arr[pState->led].pTimer->data = pState;
-+ add_timer(led_arr[pState->led].pTimer);
-+ if (pState->mode == 2) {
-+ led_off(pState);
++ }
++ else if( led_arr[pState->led].state == LED_BLINK_UP )
++ {
++ led_arr[pState->led].pTimer->expires = jiffies + HZ*(led_arr[pState->led].param)/1000;
++ led_arr[pState->led].pTimer->data = pState;
++ add_timer (led_arr[pState->led].pTimer);
++ if( pState->mode == 2 )
++ {
++ led_off(pState);
+ led_arr[pState->led].state = LED_BLINK_DOWN;
-+ } else {
-+ led_on(pState);
++ }
++ else
++ {
++ led_on(pState);
+ led_arr[pState->led].state = LED_BLINK_DOWN;
+ }
+ led_arr[pState->led].timer_running = 1;
-+ } else if (led_arr[pState->led].state == LED_FLASH) {
-+ led_arr[pState->led].pTimer->expires =
-+ jiffies + HZ * (led_arr[pState->led].param) / 1000;
-+ led_arr[pState->led].pTimer->data = pState;
-+ add_timer(led_arr[pState->led].pTimer);
-+
-+ if (led_arr[pState->led].timer_running == 0xFF) {
-+ led_off(pState);
++ }
++ else if( led_arr[pState->led].state == LED_FLASH )
++ {
++ led_arr[pState->led].pTimer->expires = jiffies + HZ*(led_arr[pState->led].param)/1000;
++ led_arr[pState->led].pTimer->data = pState;
++ add_timer (led_arr[pState->led].pTimer);
++
++ if( led_arr[pState->led].timer_running == 0xFF )
++ {
++ led_off(pState);
+ led_arr[pState->led].timer_running--;
-+ } else {
-+ led_on(pState);
++ }
++ else
++ {
++ led_on(pState);
+ led_arr[pState->led].timer_running++;
+ }
+ spin_unlock_irqrestore(&config_lock, flags);
++ return;
++ }
++ else if(led_arr[pState->led].state == LED_OFF)
++ {
++ led_off(pState);
++ led_arr[pState->led].timer_running = 0;
++ }
++ else if( led_arr[pState->led].state == LED_ON )
++ {
++ led_on(pState);
++ led_arr[pState->led].timer_running = 0;
++ }
++ spin_unlock_irqrestore(&config_lock, flags);
++ return;
++}
++/************wwzh*****************/
++#if 0
++/************end *****************/
++static ssize_t proc_read_led_fops(struct file *filp,
++ char *buf,size_t count , loff_t *offp)
++{
++ char * pdata = NULL;
++ int i = 0, j = 0, len = 0, totallen = 0;
++ char line[255];
++
++ if( *offp != 0 )
++ return 0;
++
++ pdata = buf;
++ len += sprintf(line,"LEDS Registered for use are:");
++ for( i = 0; i< MAX_LED_ID; i++)
++ if( led_arr[i].led != NULL )
++ len += sprintf(&line[len]," %d ", i );
++ line[len++] = '\n';
++
++ copy_to_user(pdata, line,len );
++ pdata += len;
++ totallen += len;
++ len = 0;
++ len = sprintf(line,"USER MODULE INFORMATION:\n");
++ copy_to_user(pdata, line,len );
++ pdata += len;
++ totallen += len;
++ len = 0;
++ for( i = 0; i< MAX_MOD_ID; i++)
++ {
++ if( modArr[i] != NULL )
++ {
++ len = sprintf(line," Module ID = %d \n" , i);
++ copy_to_user(pdata, line,len );
++ pdata += len;
++ totallen += len;
++ len = 0;
++ for( j = 0; j < MAX_STATE_ID; j++)
++ {
++ if( modArr[i]->states[j] != NULL)
++ {
++ len = sprintf(line ,
++ " State = %d , Led = %d," , j , modArr[i]->states[j]->led);
++ copy_to_user(pdata, line,len );
++ pdata += len;
++ totallen += len;
++
++ len = 0;
++ switch( modArr[i]->states[j]->mode )
++ {
++ case 1:
++ len = sprintf(line ," Mode = OFF\n");
++ break;
++ case 2:
++ len = sprintf(line ," Mode = BLINK_ON , On Time(ms) = %d\n" ,
++ (unsigned int)modArr[i]->states[j]->param);
++ break;
++ case 3:
++ len = sprintf(line ," Mode = BLINK_OFF , Off Time(ms) = %d\n" ,
++ (unsigned int)modArr[i]->states[j]->param);
++ break;
++ case 4:
++ len = sprintf(line ," Mode = ON \n");
++ break;
++ case 5:
++ len = sprintf(line ," Mode = FLASH , Time Period(ms) = %d\n" ,
++ (unsigned int)modArr[i]->states[j]->param);
++ break;
++ default:
++ break;
++
++ }
++ copy_to_user(pdata, line,len );
++ pdata += len;
++ totallen += len;
++
++ len = 0;
++ }
++ }
++ }
++ }
++ /* Return with configuration information for LEDs */
++ *offp = totallen;
++ return totallen;
++}
++static ssize_t proc_write_led_fops(struct file *filp,const char *buffer,
++ size_t count , loff_t *offp)
++{
++ char *pdata = NULL, *ptemp = NULL;
++ char line[10],temp[10];
++ int i = 0;
++ int mod = 0xFFFF , state = 0xFFFF;
++ int flag = 0;
++
++ /* Check if this write is for configuring stuff */
++ if( *(int *)(buffer) == 0xFFEEDDCC )
++ {
++ printk("<1>proc write:Calling Configuration\n");
++ config_led((unsigned long)(buffer + sizeof(int)) );
++ return count;
++ }
++
++ if( count >= 10)
++ {
++ printk("<1>proc write:Input too long,max length = %d\n",10);
++ return count;
++ }
++ memset( temp, 0x00 , 10);
++ memset( line, 0x00 , 10);
++ copy_from_user(line,buffer,count);
++ line[count] = 0x00;
++ pdata = line;
++ ptemp = temp;
++ while( flag == 0)
++ {
++ if( i > 10 )
++ break;
++ if( ((*pdata) >= '0' ) && ((*pdata) <= '9') )
++ {
++ *ptemp = *pdata ;
++ ptemp++;
++ }
++ else if( (*pdata) == ',' )
++ {
++ *ptemp = 0x00;
++ flag = 1;
++ }
++ pdata++;
++ i++;
++ };
++ if( flag == 1)
++ mod = led_atoi( temp);
++ else
++ return count;
++
++ ptemp = temp;
++ *ptemp = 0x00;
++ flag = 0;
++ while( flag == 0)
++ {
++ if( i > 10 )
++ break;
++ if( ((*pdata) >= '0' ) && ((*pdata) <= '9') )
++ {
++ *ptemp = *pdata ;
++ ptemp++;
++ }
++ else if( (*pdata) == 0x00 )
++ {
++ *ptemp = 0x00;
++ flag = 1;
++ }
++ pdata++;
++ i++;
++ };
++ if( flag == 1)
++ state = led_atoi( temp);
++ else
++ return count;
++ if( (mod == 0xFFFF) || (state == 0xFFFF))
++ return count;
++ else
++ led_operation( mod , state );
++ return count;
++}
++
++/************wwzh*******************/
++#else
++
++#define TRUE 1
++#define FALSE 0
++#define FLICK_TIME (HZ*100/1000)
++static unsigned int wan_txrx_state = 0;
++static unsigned int wlan_txrx_state = 0;
++
++void led_operation( int mod , int state)
++{
++
++ unsigned int flags;
++
++ spin_lock_irqsave(&config_lock, flags);
++
++ if( (mod >= MAX_MOD_ID) || ( state >= MAX_STATE_ID) )
++ {
++ spin_unlock_irqrestore(&config_lock, flags);
++ return;
++ }
++ if ( modArr[mod] == NULL )
++ {
++ spin_unlock_irqrestore(&config_lock, flags);
+ return;
-+ } else if (led_arr[pState->led].state == LED_OFF) {
-+ led_off(pState);
-+ led_arr[pState->led].timer_running = 0;
-+ } else if (led_arr[pState->led].state == LED_ON) {
-+ led_on(pState);
-+ led_arr[pState->led].timer_running = 0;
+ }
++ if( modArr[mod]->states[state] == NULL )
++ {
++ spin_unlock_irqrestore(&config_lock, flags);
++ return;
++ }
++ /* Call the function handler */
++ modArr[mod]->states[state]->handler(modArr[mod]->states[state]);
++
+ spin_unlock_irqrestore(&config_lock, flags);
-+ return;
+}
+
++static void wan_led_func(unsigned long data)
++{
++ if (wan_txrx_state == 0)
++ {
++ tnetd73xx_gpio_out(2, TRUE);
++ tnetd73xx_gpio_out(3, FALSE);
++ wan_txrx_state = 1;
++ }
++ else
++ {
++ tnetd73xx_gpio_out(2, FALSE);
++ tnetd73xx_gpio_out(3, FALSE);
++ wan_txrx_state = 0;
++ }
++ pWanTimer->expires = jiffies + FLICK_TIME;
++ add_timer(pWanTimer);
++}
++//wwzh for wireless
++#if 0
++static void wlan_led_func(unsigned long data)
++{
++ if (wlan_txrx_state == 0)
++ {
++ tnetd73xx_gpio_out(12, TRUE);
++ tnetd73xx_gpio_out(13, FALSE);
++ wlan_txrx_state = 1;
++ }
++ else
++ {
++ tnetd73xx_gpio_out(12, FALSE);
++ tnetd73xx_gpio_out(13, FALSE);
++ wlan_txrx_state = 0;
++
++ }
++ pWlanTimer->expires = jiffies + FLICK_TIME;
++ add_timer(pWlanTimer);
++}
++#endif
++
++void led_active(int mod, int state)
++{
++ unsigned int flags = 0;
++
++//printk("mod = %d state = %d\n", mod, state);
++ spin_lock_irqsave(&config_lock, flags);
++ if ((mod >= 5) || (state >= 5))
++ {
++ spin_unlock_irqrestore(&config_lock, flags);
++ return;
++ }
++
++ switch (mod)
++ {
++ case 2: /*system led */
++ sys_mod_state = state;
++ switch (state)
++ {
++ case 1:
++ break;
++ case 2: /*sys led flashing green */
++ tnetd73xx_gpio_out(4, FALSE);
++ tnetd73xx_gpio_out(5, TRUE);
++ tnetd73xx_gpio_out(8, TRUE);
++ break;
++ case 3: /*sys led solid green */
++ tnetd73xx_gpio_out(4, TRUE);
++ tnetd73xx_gpio_out(5, TRUE);
++ tnetd73xx_gpio_out(8, TRUE);
++
++ break;
++ case 4: /*sys fail red */
++ tnetd73xx_gpio_out(4, TRUE);
++ tnetd73xx_gpio_out(5, FALSE);
++ tnetd73xx_gpio_out(8, FALSE);
++ break;
++ default:
++ break;
++ }
++ break;
++ case 3: /*wan led */
++ wan_mod_state = state;
++ switch (state)
++ {
++ case 1: /*no wan interface*/
++ if (pWanTimer)
++ {
++ del_timer(pWanTimer);
++ kfree(pWanTimer);
++ pWanTimer = NULL;
++ }
++ tnetd73xx_gpio_out(2, FALSE);
++ tnetd73xx_gpio_out(3, FALSE);
++ break;
++ case 2: /*wan connected */
++ if (pWanTimer)
++ {
++ del_timer(pWanTimer);
++ kfree(pWanTimer);
++ pWanTimer = NULL;
++ }
++ tnetd73xx_gpio_out(2, TRUE);
++ tnetd73xx_gpio_out(3, FALSE);
++ break;
++ case 3: /*rx/tx activity */
++ if (pWanTimer != NULL)
++ break;
++
++ pWanTimer = kmalloc(sizeof(struct timer_list), GFP_KERNEL);
++ init_timer(pWanTimer);
++
++ pWanTimer->function = wan_led_func;
++ pWanTimer->data = 0;
++ pWanTimer->expires = jiffies + FLICK_TIME;
++ tnetd73xx_gpio_out(2, FALSE);
++ tnetd73xx_gpio_out(3, FALSE);
++ wan_txrx_state = 0;
++ add_timer(pWanTimer);
++
++ break;
++ case 4: /*no ipaddress */
++ if (pWanTimer)
++ {
++ del_timer(pWanTimer);
++ kfree(pWanTimer);
++ pWanTimer = NULL;
++ }
++ tnetd73xx_gpio_out(2, FALSE);
++ tnetd73xx_gpio_out(3, TRUE);
++ break;
++ default:
++ if (pWanTimer)
++ {
++ del_timer(pWanTimer);
++ kfree(pWanTimer);
++ pWanTimer = NULL;
++ }
++ break;
++ }
++ break;
++ //wwzh for wireless
++ #if 0
++ case 4: /*wlan led */
++ wlan_mod_state = state;
++ switch (state)
++ {
++ case 1: /* wlan off */
++ if (pWlanTimer)
++ {
++ del_timer(pWlanTimer);
++ kfree(pWlanTimer);
++ pWlanTimer = NULL;
++ }
++ tnetd73xx_gpio_out(12, FALSE);
++ tnetd73xx_gpio_out(13, FALSE);
++ break;
++ case 2: /* wlan ready */
++ if (pWlanTimer)
++ {
++ del_timer(pWlanTimer);
++ kfree(pWlanTimer);
++ pWlanTimer = NULL;
++ }
++ tnetd73xx_gpio_out(12, TRUE);
++ tnetd73xx_gpio_out(13, FALSE);
++ break;
++ case 3: /* wlan rx/tx activity */
++ if (pWlanTimer != NULL)
++ break;
++
++ pWlanTimer = kmalloc(sizeof(struct timer_list), GFP_KERNEL);
++ init_timer(pWlanTimer);
++
++ pWlanTimer->function = wlan_led_func;
++ pWlanTimer->data = 0;
++ pWlanTimer->expires = jiffies + FLICK_TIME;
++ tnetd73xx_gpio_out(12, FALSE);
++ tnetd73xx_gpio_out(13, FALSE);
++ wlan_txrx_state = 0;
++ add_timer(pWlanTimer);
++
++ break;
++ default:
++ if (pWlanTimer)
++ {
++ del_timer(pWlanTimer);
++ kfree(pWlanTimer);
++ pWlanTimer = NULL;
++ }
++
++ break;
++ }
++ break;
++ #endif //for wireless
++ default:
++ break;
++ }
++ spin_unlock_irqrestore(&config_lock, flags);
++}
+static ssize_t proc_read_led_fops(struct file *filp,
-+ char *buf, size_t count, loff_t * offp)
++ char *buf,size_t count , loff_t *offp)
+{
+ char *pdata = NULL;
+ int i = 0, j = 0, len = 0, totallen = 0;
+ char line[255];
-+
++
+ if (*offp != 0)
+ return 0;
-+
+ pdata = buf;
-+ len += sprintf(line, "LEDS Registered for use are:");
-+ for (i = 0; i < MAX_LED_ID; i++)
-+ if (led_arr[i].led != NULL)
-+ len += sprintf(&line[len], " %d ", i);
-+ line[len++] = '\n';
-+
-+ copy_to_user(pdata, line, len);
-+ pdata += len;
-+ totallen += len;
-+ len = 0;
+ len = sprintf(line, "USER MODULE INFORMATION:\n");
+ copy_to_user(pdata, line, len);
+ pdata += len;
+ totallen += len;
+ len = 0;
-+ for (i = 0; i < MAX_MOD_ID; i++) {
-+ if (modArr[i] != NULL) {
-+ len = sprintf(line, " Module ID = %d \n", i);
++
++ //*******add Module 1 , this Module is ADSL ********/
++ for (i = 0; i < MAX_MOD_ID; i++)
++ {
++ if (modArr[i] != NULL)
++ {
++ len = sprintf(line, " Module ID = %d\n", i);
+ copy_to_user(pdata, line, len);
+ pdata += len;
+ totallen += len;
+ len = 0;
-+ for (j = 0; j < MAX_STATE_ID; j++) {
-+ if (modArr[i]->states[j] != NULL) {
-+ len = sprintf(line, " State = %d , Led = %d,", j,
-+ modArr[i]->states[j]->led);
++ for(j = 0; j < MAX_STATE_ID; j++)
++ {
++ if (modArr[i]->states[j] != NULL)
++ {
++ len = sprintf(line, "State =%d, Led = %d,", j, modArr[i]->states[j]->led);
+ copy_to_user(pdata, line, len);
+ pdata += len;
+ totallen += len;
-+
+ len = 0;
-+ switch (modArr[i]->states[j]->mode) {
-+ case 1:
-+ len = sprintf(line, " Mode = OFF\n");
-+ break;
-+ case 2:
-+ len = sprintf(line, " Mode = BLINK_ON , On Time(ms) = %d\n",
-+ (unsigned int) modArr[i]->states[j]->
-+ param);
-+ break;
-+ case 3:
-+ len = sprintf(line, " Mode = BLINK_OFF , Off Time(ms) = %d\n",
-+ (unsigned int) modArr[i]->states[j]->
-+ param);
-+ break;
-+ case 4:
-+ len = sprintf(line, " Mode = ON \n");
-+ break;
-+ case 5:
-+ len = sprintf(line, " Mode = FLASH , Time Period(ms) = %d\n",
-+ (unsigned int) modArr[i]->states[j]->
-+ param);
-+ break;
-+ default:
-+ break;
-+
++ switch(modArr[i]->states[j]->mode)
++ {
++ case 1:
++ len = sprintf(line, "Mode = OFF\n");
++ break;
++ case 2:
++ len = sprintf(line, "Mode = BLINK_ON, On Time(ms) = %d\n", (unsigned int)modArr[i]->states[j]->param);
++ break;
++ case 3:
++ len = sprintf(line, "Mode = BLINK_OFF, Off Time(ms) = %d\n", (unsigned int)modArr[i]->states[j]->param);
++ break;
++ case 4:
++ len = sprintf(line, "Mode = On\n");
++ break;
++ case 5:
++ len = sprintf(line, "Mode = FLASH, Time Period(ms) = %d\n", (unsigned int)modArr[i]->states[j]->param);
++ break;
++ default:
++ break;
+ }
+ copy_to_user(pdata, line, len);
+ pdata += len;
+ totallen += len;
-+
+ len = 0;
+ }
-+ }
++ }
+ }
++
++ }
++
++ len = sprintf(line, "Module ID = 2(system led)\n");
++ copy_to_user(pdata, line, len);
++ pdata += len;
++ totallen += len;
++ len = 0;
++ switch(sys_mod_state)
++ {
++ case 1:
++ len = sprintf(line, "State = OFF\n");
++ break;
++ case 2:
++ len = sprintf(line, "State = Booting\n");
++ break;
++ case 3:
++ len = sprintf(line, "State = System Ready\n");
++ break;
++ case 4:
++ len = sprintf(line, "State = System Failure\n");
++ break;
++ default:
++ break;
+ }
-+ /* Return with configuration information for LEDs */
++ copy_to_user(pdata, line, len);
++ pdata += len;
++ totallen += len;
++ len = 0;
++
++ len = sprintf(line, "Module ID = 3(WAN led)\n");
++ copy_to_user(pdata, line, len);
++ pdata += len;
++ totallen += len;
++ len = 0;
++ switch(wan_mod_state)
++ {
++ case 1:
++ len = sprintf(line, "State = OFF\n");
++ break;
++ case 2:
++ len = sprintf(line, "State = Wan Connected\n");
++ break;
++ case 3:
++ len = sprintf(line, "State = Wan Tx/Rx Activity\n");
++ break;
++ case 4:
++ len = sprintf(line, "State = Wan Connect Failure\n");
++ break;
++ default:
++ break;
++ }
++ copy_to_user(pdata, line, len);
++ pdata += len;
++ totallen += len;
++ len = 0;
++
++//wwzh for wireless
++#if 0
++ len = sprintf(line, "Module ID = 4(WLAN led)\n");
++ copy_to_user(pdata, line, len);
++ pdata += len;
++ totallen += len;
++ len = 0;
++ switch(wlan_mod_state)
++ {
++ case 1:
++ len = sprintf(line, "State = OFF\n");
++ break;
++ case 2:
++ len = sprintf(line, "State = wlan Ready\n");
++ break;
++ case 3:
++ len = sprintf(line, "State = wlan rx/tx activity\n");
++ break;
++ default:
++ break;
++ }
++ copy_to_user(pdata, line, len);
++ pdata += len;
++ totallen += len;
++ len = 0;
++#endif //for wireless
++
+ *offp = totallen;
+ return totallen;
+}
-+
-+static ssize_t proc_write_led_fops(struct file *filp, const char *buffer, size_t count, loff_t * offp)
++static ssize_t proc_write_led_fops(struct file *filp,const char *buffer,
++ size_t count , loff_t *offp)
+{
+ char *pdata = NULL, *ptemp = NULL;
+ char line[10], temp[10];
+ int i = 0;
-+ int mod = 0xFFFF, state = 0xFFFF;
++ int mod = 0xffff, state = 0xffff;
+ int flag = 0;
+
-+ /* Check if this write is for configuring stuff */
-+ if (*(int *) (buffer) == 0xFFEEDDCC) {
-+ printk("<1>proc write:Calling Configuration\n");
-+ config_led((unsigned long) (buffer + sizeof(int)));
-+ return count;
++ /* Check if this write is for configuring ADSL */
++ if( *(int *)(buffer) == 0xFFEEDDCC )
++ {
++ printk("<1>proc write:Calling Configuration\n");
++ config_led((unsigned long)(buffer + sizeof(int)) );
++ return count;
+ }
+
-+ if (count >= 10) {
-+ printk("<1>proc write:Input too long,max length = %d\n", 10);
++ if (count > 10)
++ {
++ printk("<1> proc write: Input too long, max length = 10\n");
+ return count;
+ }
+ memset(temp, 0x00, 10);
+ copy_from_user(line, buffer, count);
+ line[count] = 0x00;
+ pdata = line;
-+ ptemp = temp;
-+ while (flag == 0) {
++ ptemp = temp;
++
++ while (flag == 0)
++ {
+ if (i > 10)
+ break;
-+ if (((*pdata) >= '0') && ((*pdata) <= '9')) {
++ if (((*pdata) >= '0') && ((*pdata) <= '9'))
++ {
+ *ptemp = *pdata;
+ ptemp++;
-+ } else if ((*pdata) == ',') {
++ }
++ else if ((*pdata) == ',')
++ {
+ *ptemp = 0x00;
+ flag = 1;
+ }
+ pdata++;
+ i++;
-+ };
++ }
+ if (flag == 1)
+ mod = led_atoi(temp);
+ else
+ return count;
-+
++
+ ptemp = temp;
+ *ptemp = 0x00;
+ flag = 0;
-+ while (flag == 0) {
++
++ while(flag == 0)
++ {
+ if (i > 10)
+ break;
-+ if (((*pdata) >= '0') && ((*pdata) <= '9')) {
++ if (((*pdata) >= '0') && ((*pdata) <= '9'))
++ {
+ *ptemp = *pdata;
+ ptemp++;
-+ } else if ((*pdata) == 0x00) {
++ }
++ else if ((*pdata) == 0x00)
++ {
+ *ptemp = 0x00;
+ flag = 1;
+ }
+ pdata++;
+ i++;
-+ };
++ }
+ if (flag == 1)
+ state = led_atoi(temp);
+ else
+ if ((mod == 0xFFFF) || (state == 0xFFFF))
+ return count;
+ else
-+ led_operation(mod, state);
-+ return count;
++ {
++ if (mod != 4)
++ led_active(mod, state);
++ else
++ led_operation(mod, state);
++ }
++ return 1;
+}
-+
++#endif
++/************end *******************/
+static int config_led(unsigned long y)
+{
-+ config_elem_t *pcfg = NULL;
-+ char *pdata = NULL;
-+ int i;
-+ int length = 0, number = 0;
++ config_elem_t *pcfg = NULL;
++ char *pdata = NULL;
++ int i;
++ int length = 0 , number = 0;
+ unsigned int flags;
+
+ spin_lock_irqsave(&config_lock, flags);
+
-+ /* ioctl to configure */
-+ length = *((int *) y);
-+ pdata = (char *) y + sizeof(int);
-+ number = (length - sizeof(int)) / sizeof(config_elem_t);
-+ pcfg = (config_elem_t *) (pdata);
-+
-+ /* Check if an earlier configuration exists IF yes free it up */
-+ free_memory();
-+
-+ for (i = 0; i < number; i++) {
-+ /* If no structure has been allocated for the module do so */
-+ if (modArr[pcfg->name] == NULL) {
-+ printk("<1>module = %d\n", pcfg->name);
-+ if (pcfg->name >= MAX_MOD_ID) {
-+ printk
-+ ("<1>Exiting Configuration: Module ID too large %d\n",
-+ pcfg->name);
-+ free_memory();
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return -1;
-+ }
-+ modArr[pcfg->name] = kmalloc(sizeof(mod_entry_t), GFP_KERNEL);
-+ if (modArr[pcfg->name] == NULL) {
-+ printk
-+ ("<1>Exiting Configuration: Error in allocating memory\n");
-+ free_memory();
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return -1;
++ /* ioctl to configure */
++ length = *((int*)y);
++ pdata = (char *)y + sizeof(int);
++ number = (length - sizeof(int))/sizeof(config_elem_t);
++ pcfg = (config_elem_t *)(pdata);
++
++ /* Check if an earlier configuration exists IF yes free it up */
++ free_memory();
++
++ for ( i = 0 ; i < number ; i++ )
++ {
++ /* If no structure has been allocated for the module do so */
++ if ( modArr[pcfg->name] == NULL )
++ {
++ printk("<1>module = %d\n",pcfg->name);
++ if( pcfg->name >= MAX_MOD_ID)
++ {
++ printk("<1>Exiting Configuration: Module ID too large %d\n",pcfg->name);
++ free_memory();
++ spin_unlock_irqrestore(&config_lock, flags);
++ return -1;
++ }
++ modArr[pcfg->name] = kmalloc(sizeof(mod_entry_t),GFP_KERNEL);
++ if(modArr[pcfg->name] == NULL)
++ {
++ printk("<1>Exiting Configuration: Error in allocating memory\n");
++ free_memory();
++ spin_unlock_irqrestore(&config_lock, flags);
++ return -1;
++ }
++ memset( modArr[pcfg->name], 0x00, sizeof(mod_entry_t));
+ }
-+ memset(modArr[pcfg->name], 0x00, sizeof(mod_entry_t));
-+ }
+
-+ /* if no structure is allocated previously for this state
-+ allocate a structure, if it's already there fill it up */
-+ if (modArr[pcfg->name]->states[pcfg->state] == NULL) {
-+ printk("<1>STATE = %d\n", pcfg->state);
-+ if (pcfg->state >= MAX_STATE_ID) {
-+ printk("<1>Exiting Configuration: State ID too large\n");
-+ free_memory();
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return -1;
++ /* if no structure is allocated previously for this state
++ allocate a structure, if it's already there fill it up */
++ if( modArr[pcfg->name]->states[pcfg->state] == NULL)
++ {
++ printk("<1>STATE = %d\n",pcfg->state);
++ if( pcfg->state >= MAX_STATE_ID)
++ {
++ printk("<1>Exiting Configuration: State ID too large\n");
++ free_memory();
++ spin_unlock_irqrestore(&config_lock, flags);
++ return -1;
++ }
++ modArr[pcfg->name]->states[pcfg->state] =
++ kmalloc(sizeof(state_entry_t),GFP_KERNEL);
++ if( modArr[pcfg->name]->states[pcfg->state] == NULL)
++ {
++ free_memory();
++ spin_unlock_irqrestore(&config_lock, flags);
++ return -1;
++ }
++ memset( modArr[pcfg->name]->states[pcfg->state], 0x00, sizeof(state_entry_t));
+ }
-+ modArr[pcfg->name]->states[pcfg->state] =
-+ kmalloc(sizeof(state_entry_t), GFP_KERNEL);
-+ if (modArr[pcfg->name]->states[pcfg->state] == NULL) {
++ /* Fill up the fields of the state */
++ if( pcfg->led >= MAX_LED_ID)
++ {
++ printk("<1>led = %d\n",pcfg->led);
+ free_memory();
+ spin_unlock_irqrestore(&config_lock, flags);
+ return -1;
+ }
-+ memset(modArr[pcfg->name]->states[pcfg->state], 0x00,
-+ sizeof(state_entry_t));
-+ }
-+ /* Fill up the fields of the state */
-+ if (pcfg->led >= MAX_LED_ID) {
-+ printk("<1>led = %d\n", pcfg->led);
-+ free_memory();
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return -1;
-+ }
-+ modArr[pcfg->name]->states[pcfg->state]->led = pcfg->led;
-+ modArr[pcfg->name]->states[pcfg->state]->mode = pcfg->mode;
-+ modArr[pcfg->name]->states[pcfg->state]->param = pcfg->param;
-+ switch (pcfg->mode) {
-+ case 1:
-+ modArr[pcfg->name]->states[pcfg->state]->handler =
-+ board_led_link_down;
-+ break;
-+ case 2:
-+ case 3:
-+ case 5:
-+ if (pcfg->mode == 2)
-+ modArr[pcfg->name]->states[pcfg->state]->handler =
-+ board_led_activity_on;
-+ else if (pcfg->mode == 3)
-+ modArr[pcfg->name]->states[pcfg->state]->handler =
-+ board_led_activity_off;
-+ else
-+ modArr[pcfg->name]->states[pcfg->state]->handler =
-+ board_led_link_flash;
-+ break;
-+ case 4:
-+ modArr[pcfg->name]->states[pcfg->state]->handler =
-+ board_led_link_up;
-+ break;
-+ default:
-+ printk("<1>Exiting Configuration: Unknown LED Mode\n");
-+ free_memory();
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return -1;
-+ }
-+ pcfg++;
-+ }
++ modArr[pcfg->name]->states[pcfg->state]->led = pcfg->led;
++ modArr[pcfg->name]->states[pcfg->state]->mode = pcfg->mode;
++ modArr[pcfg->name]->states[pcfg->state]->param = pcfg->param;
++ switch(pcfg->mode)
++ {
++ case 1:
++ modArr[pcfg->name]->states[pcfg->state]->handler = board_led_link_down;
++ break;
++ case 2:
++ case 3:
++ case 5:
++ if( pcfg->mode == 2 )
++ modArr[pcfg->name]->states[pcfg->state]->handler = board_led_activity_on;
++ else if( pcfg->mode == 3)
++ modArr[pcfg->name]->states[pcfg->state]->handler = board_led_activity_off;
++ else
++ modArr[pcfg->name]->states[pcfg->state]->handler = board_led_link_flash;
++ break;
++ case 4:
++ modArr[pcfg->name]->states[pcfg->state]->handler = board_led_link_up;
++ break;
++ default:
++ printk("<1>Exiting Configuration: Unknown LED Mode\n");
++ free_memory();
++ spin_unlock_irqrestore(&config_lock, flags);
++ return -1;
++ }
++ pcfg++;
++ }
+ spin_unlock_irqrestore(&config_lock, flags);
-+ return 0;
++ return 0;
+}
+
+
+int __init led_init(void)
+{
+
-+ /* Clear our memory */
-+ memset(modArr, 0x00, sizeof(mod_entry_t *) * MAX_MOD_ID);
-+ memset(led_arr, 0x00, sizeof(led_data_t *) * MAX_LED_ID);
++ /* Clear our memory */
++ memset(modArr,0x00,sizeof(mod_entry_t *)*MAX_MOD_ID);
++ memset(led_arr,0x00,sizeof(led_data_t *)*MAX_LED_ID);
+
+ /* Create spin lock for config data structure */
-+ config_lock = SPIN_LOCK_UNLOCKED;
-+
-+#if 0
-+ /* Create directory */
-+ led_proc_dir = proc_mkdir("led_mod", NULL);
-+ if (led_proc_dir == NULL)
-+ goto out;
-+#endif
-+
-+ /* Create adsl file */
-+ led_file = create_proc_entry("led", 0777, NULL);
-+ if (led_file == NULL)
-+ goto led_file;
-+
-+ led_file->owner = THIS_MODULE;
-+ led_file->proc_fops = &led_fops;
-+
-+ memset(modArr, 0x00, sizeof(mod_entry_t *) * MAX_MOD_ID);
-+
-+ /* Ron add for ADSL LED blink */
-+ my_mode = 1;
-+ my_led_init(GPIO_ADSL_ACT, 0, -1);
-+ my_led_init(GPIO_ADSL_DOWN, 0, -1);
-+ init_timer(&my_led_timer);
-+ my_led_timer.function = my_led_blink_timer;
-+ my_led_timer.data = 0;
-+ my_led_timer.expires = jiffies + BLINK_SLOW;
-+ add_timer(&my_led_timer);
-+ /* Ron add for ADSL LED blink */
-+ return 0;
++ config_lock=SPIN_LOCK_UNLOCKED;
++
++ /* Create directory */
++ led_proc_dir = proc_mkdir("led", NULL);
++ if( led_proc_dir == NULL )
++ goto out;
++
++ /* Create adsl file */
++ led_file = create_proc_entry("led", 0777, led_proc_dir);
++ if( led_file == NULL)
++ goto led_file;
++ led_file->owner = THIS_MODULE;
++ led_file->proc_fops = &led_fops;
++
++ memset( modArr , 0x00 , sizeof(mod_entry_t *) * MAX_MOD_ID);
++ /* Reset the GPIO pins */
++ board_gpio_init();
++
++ /* Register the UART controlled LEDS */
++ uart_led_init();
++ /* Create the usb proc file */
++ avalanche_leds_init();
++ return 0;
+
+ led_file:
-+ remove_proc_entry("led", NULL);
++ remove_proc_entry("led",led_proc_dir);
+ out:
-+ return 0;
++ return 0;
+
+}
+
-+void led_exit(void)
++void led_exit()
+{
-+ remove_proc_entry("led", NULL);
++ remove_proc_entry("led", led_proc_dir);
+}
+
-+void led_operation(int mod, int state)
-+{
-+
-+ unsigned int flags;
-+
-+ spin_lock_irqsave(&config_lock, flags);
-+#if 1
-+ /* Ron Add for ADSL LED blink */
-+ //printk("mod==%d state==%d\n",mod,state);
-+
-+ if (mod == 1) {
-+ switch (state) {
-+ /* off */
-+ case 1:
-+ my_mode = 1;
-+ my_blink_count = 0;
-+ my_led_off(GPIO_ADSL_ACT, -1);
-+ my_led_off(GPIO_ADSL_DOWN, -1);
-+ break;
-+ /* sync */
-+ case 2:
-+ if (my_mode == 1) {
-+ my_mode = 2;
-+ my_led_off(GPIO_ADSL_ACT, -1);
-+ my_blink_count++;
-+ }
-+ break;
-+ /* on */
-+ case 3:
-+ my_mode = 3;
-+ my_blink_count = 0;
-+ my_led_off(GPIO_ADSL_DOWN, -1);
-+ my_led_on(GPIO_ADSL_ACT, -1);
-+ break;
-+ /* off */
-+ case 4:
-+ my_mode = 4;
-+ my_led_off(GPIO_ADSL_DOWN, -1);
-+ my_blink_count++;
-+ break;
-+ }
-+ } /* Ron add for ADSL LED Blink */
-+#endif
-+ if ((mod >= MAX_MOD_ID) || (state >= MAX_STATE_ID)) {
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return;
-+ }
-+ if (modArr[mod] == NULL) {
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return;
-+ }
-+ if (modArr[mod]->states[state] == NULL) {
-+ spin_unlock_irqrestore(&config_lock, flags);
-+ return;
-+ }
-+ /* Call the function handler */
-+ modArr[mod]->states[state]->handler(modArr[mod]->states[state]);
-+
-+ spin_unlock_irqrestore(&config_lock, flags);
-+}
++module_init(led_init);
++module_exit(led_exit);
+
-+void register_led_drv(int device, led_reg_t * pInfo)
++void register_led_drv( int device , led_reg_t *pInfo)
+{
+ unsigned int flags;
+ struct timer_list *pTimer = NULL;
+ spin_lock_irqsave(&config_lock, flags);
+
+ led_arr[device].led = pInfo;
-+ if (led_arr[device].led->init != 0x00)
-+ led_arr[device].led->init(led_arr[device].led->param);
-+ if (led_arr[device].led->offfunc != 0x00)
-+ led_arr[device].led->offfunc(led_arr[device].led->param);
++ if( led_arr[device].led->init != 0x00)
++ led_arr[device].led->init(led_arr[device].led->param);
++ if( led_arr[device].led->offfunc != 0x00)
++ led_arr[device].led->offfunc(led_arr[device].led->param);
+
+ /* Create a timer for blinking */
-+ pTimer = kmalloc(sizeof(struct timer_list), GFP_KERNEL);
-+ init_timer(pTimer);
++ pTimer = kmalloc(sizeof(struct timer_list),GFP_KERNEL);
++ init_timer( pTimer );
+ pTimer->function = led_timer_func;
+ pTimer->data = 0;
-+ led_arr[device].pTimer = pTimer;
-+ led_arr[device].timer_running = 0;
++ led_arr[device].pTimer = pTimer;
++ led_arr[device].timer_running = 0;
+
+ spin_unlock_irqrestore(&config_lock, flags);
+
-+ return;
++ return;
+}
+
-+void deregister_led_drv(int device)
++void deregister_led_drv( int device)
+{
+ unsigned int flags;
+
+ spin_lock_irqsave(&config_lock, flags);
+ led_arr[device].led = NULL;
+
-+ if (led_arr[device].pTimer != NULL) {
++ if( led_arr[device].pTimer != NULL)
++ {
+ del_timer(led_arr[device].pTimer);
+ kfree(led_arr[device].pTimer);
+ }
+ spin_unlock_irqrestore(&config_lock, flags);
+
-+ return;
++ return;
+}
+
-+module_init(led_init);
-+module_exit(led_exit);
-+
-+
-+EXPORT_SYMBOL_NOVERS(led_init);
+EXPORT_SYMBOL_NOVERS(led_operation);
+EXPORT_SYMBOL_NOVERS(register_led_drv);
+EXPORT_SYMBOL_NOVERS(deregister_led_drv);
++
+diff -urN linux.old/drivers/char/avalanche_led/leds.c linux.dev/drivers/char/avalanche_led/leds.c
+--- linux.old/drivers/char/avalanche_led/leds.c 1970-01-01 01:00:00.000000000 +0100
++++ linux.dev/drivers/char/avalanche_led/leds.c 2005-07-22 06:52:42.976338184 +0200
+@@ -0,0 +1,133 @@
++#include <linux/config.h>
++#include <linux/init.h>
++#include <linux/delay.h>
++#include <asm/ar7/avalanche_regs.h>
++#include <linux/spinlock.h>
++#include <linux/timer.h>
++#include <linux/sched.h>
++#include <linux/module.h>
++#include <linux/proc_fs.h>
++#include <asm/uaccess.h>
++#include <linux/fs.h>
++
++#include <asm/ar7/ledapp.h>
++
++#if defined(CONFIG_AR5D01) || defined(CONFIG_AR5W01) || defined(CONFIG_AR7)
++
++#define ETH_MASK 0x01
++#define USB_MASK 0x02
++
++static struct proc_dir_entry *usb_file;
++static ssize_t proc_read_usb_fops(struct file *filp,
++ char *buf,size_t count , loff_t *offp);
++struct file_operations usb_fops = {read: proc_read_usb_fops};
++
++typedef struct mod_states{
++ int module;
++ int activity;
++ int linkup;
++ int idle;
++}mod_states_t;
++
++mod_states_t state_arr[] = {
++ { MOD_ETH,DEF_ETH_ACTIVITY,DEF_ETH_LINK_UP,DEF_ETH_IDLE },
++ { MOD_USB,DEF_USB_ACTIVITY,DEF_USB_LINK_UP,DEF_USB_IDLE },
++ { MOD_LAN,DEF_LAN_ACTIVITY,DEF_LAN_LINK_UP,DEF_LAN_IDLE }
++ };
++
++unsigned char device_links = 0; /* Bitmask with the devices that are up */
++
++
++void avalanche_led_activity_pulse(unsigned long device)
++{
++ /* If device link is not up return */
++ if( !(device_links & (unsigned char)(1 << device)))
++ return;
++#ifdef MULTIPLEX_LED
++ led_operation( state_arr[2].module, state_arr[2].activity);
++#else
++ led_operation( state_arr[device].module, state_arr[device].activity);
++#endif
++}
++
++void avalanche_led_link_up( unsigned long device )
++{
++
++ /* If already UP ignore */
++ if( device_links & (unsigned char)(1 << device))
++ return;
++ /* Turn on the bit for the device */
++ device_links |= (unsigned char)(1 << device);
++#ifdef MULTIPLEX_LED
++ led_operation( state_arr[2].module, state_arr[2].linkup);
++#else
++ led_operation( state_arr[device].module, state_arr[device].linkup);
++#endif
++}
++
++void avalanche_led_link_down ( unsigned long device )
++{
++
++ /* If already DOWN ignore */
++ if( !(device_links & (unsigned char)(1 << device)))
++ return;
++
++ /* Turn off the bit for the device */
++ device_links &= ~(unsigned char)(1 << device);
++#ifdef MULTIPLEX_LED
++ /* If no links, then shut the LED off */
++ if(!device_links)
++ led_operation( state_arr[2].module, state_arr[2].idle);
++#else
++ led_operation( state_arr[device].module, state_arr[device].idle);
++#endif
++}
++
++static ssize_t proc_read_usb_fops(struct file *filp,
++ char *buf,size_t count , loff_t *offp)
++{
++ char * pdata = NULL;
++ char line[3];
++ if( *offp != 0 )
++ return 0;
++ pdata = buf;
++ if( device_links & USB_MASK)
++ sprintf(line,"%s\n","1");
++ else
++ sprintf(line,"%s\n","0");
++ copy_to_user(pdata,line,2);
++ *offp = 2;
++ return 2;
++}
++
++
++void avalanche_leds_init(void)
++{
++ /* Create usb link proc file */
++ usb_file = create_proc_entry("avalanche/usb_link", 0444, NULL);
++ if( usb_file == NULL)
++ return;
++ usb_file->owner = THIS_MODULE;
++ usb_file->proc_fops = &usb_fops;
++ return;
++}
++
++EXPORT_SYMBOL(avalanche_led_activity_pulse);
++EXPORT_SYMBOL(avalanche_led_link_up);
++EXPORT_SYMBOL(avalanche_led_link_down);
++
++#else
++/* We make a dummy init routine for the platforms that do not support this led
++ API
++*/
++
++void avalanche_leds_init(void)
++{
++}
++
++#endif
++
++
++
++
++
diff -urN linux.old/drivers/char/avalanche_led/Makefile linux.dev/drivers/char/avalanche_led/Makefile
--- linux.old/drivers/char/avalanche_led/Makefile 1970-01-01 01:00:00.000000000 +0100
-+++ linux.dev/drivers/char/avalanche_led/Makefile 2005-07-11 02:42:24.191796312 +0200
++++ linux.dev/drivers/char/avalanche_led/Makefile 2005-07-22 06:52:42.977338032 +0200
@@ -0,0 +1,23 @@
+# File: drivers/char/avalanche_led/Makefile
+#
+
+EXTRA_CFLAGS := -I$(TOPDIR)/include/asm/ar7
+
-+export-objs := ledmod.o
++export-objs := ledmod.o leds.o
+
-+avalanche_led-objs := ledmod.o
++avalanche_led-objs := ledmod.o gpio.o uartled.o leds.o
+
+include $(TOPDIR)/Rules.make
+
+
+clean:
+ rm -f core *.o *.a *.s
+diff -urN linux.old/drivers/char/avalanche_led/uartled.c linux.dev/drivers/char/avalanche_led/uartled.c
+--- linux.old/drivers/char/avalanche_led/uartled.c 1970-01-01 01:00:00.000000000 +0100
++++ linux.dev/drivers/char/avalanche_led/uartled.c 2005-07-22 06:52:42.977338032 +0200
+@@ -0,0 +1,55 @@
++#include <linux/kernel.h>
++#include <asm/uaccess.h>
++#include <linux/spinlock.h>
++#include <asm/ar7/avalanche_regs.h>
++#include <asm/ar7/ledapp.h>
++
++#define UART_LED_REG (*(volatile unsigned int *)(UARTA_BASE + 0x10))
++
++static spinlock_t device_lock;
++led_reg_t temp1[2];
++
++static void uart_led_on(unsigned long param)
++{
++ unsigned long flags;
++
++ spin_lock_irqsave(&device_lock,flags);
++ UART_LED_REG &= 0xFFFD;
++ spin_unlock_irqrestore(&device_lock, flags);
++}
++
++static void uart_led_off ( unsigned long param )
++{
++ unsigned int flags = 0x00;
++ spin_lock_irqsave(&device_lock, flags);
++ UART_LED_REG |= 0x02;
++ spin_unlock_irqrestore(&device_lock, flags);
++}
++
++void uart_led_init(void)
++{
++
++#if defined(CONFIG_AR5D01)
++ /* Register led 6 UART Pin 1 */
++ temp1[0].param = 0;
++ temp1[0].init = NULL;
++ temp1[0].onfunc = uart_led_on;
++ temp1[0].offfunc = uart_led_off;
++ register_led_drv( 6 , &temp1[0]);
++#endif
++
++#if defined(CONFIG_AR5W01)
++ /* Register led 8 UART Pin 1 */
++ temp1[0].param = 0;
++ temp1[0].init = NULL;
++ temp1[0].onfunc = uart_led_on;
++ temp1[0].offfunc = uart_led_off;
++ register_led_drv( 8 , &temp1[0]);
++#endif
++
++ /* Initialize the link mask */
++ device_lock = SPIN_LOCK_UNLOCKED;
++
++ return;
++}
++
diff -urN linux.old/drivers/char/Config.in linux.dev/drivers/char/Config.in
---- linux.old/drivers/char/Config.in 2005-07-10 20:53:55.650624032 +0200
-+++ linux.dev/drivers/char/Config.in 2005-07-10 20:50:43.556826000 +0200
+--- linux.old/drivers/char/Config.in 2005-07-10 20:53:55.650624000 +0200
++++ linux.dev/drivers/char/Config.in 2005-07-22 06:52:58.716945248 +0200
@@ -133,6 +133,10 @@
fi
fi
fi
+if [ "$CONFIG_AR7" = "y" ]; then
-+ bool 'Enable LED support' CONFIG_MIPS_AVALANCHE_LED
++ bool 'Enable LED support' CONFIG_AR7_LED
+fi
+
if [ "$CONFIG_EXPERIMENTAL" = "y" -a "$CONFIG_ZORRO" = "y" ]; then
tristate 'Commodore A2232 serial support (EXPERIMENTAL)' CONFIG_A2232
fi
diff -urN linux.old/drivers/char/Makefile linux.dev/drivers/char/Makefile
---- linux.old/drivers/char/Makefile 2005-07-10 20:53:55.651623880 +0200
-+++ linux.dev/drivers/char/Makefile 2005-07-10 20:50:43.556826000 +0200
-@@ -190,6 +190,19 @@
+--- linux.old/drivers/char/Makefile 2005-07-10 20:53:55.651623000 +0200
++++ linux.dev/drivers/char/Makefile 2005-07-22 06:53:35.321380528 +0200
+@@ -190,6 +190,12 @@
obj-$(CONFIG_PCI) += keyboard.o $(KEYMAP)
endif
+#
+# Texas Intruments LED driver
+#
-+ifeq ($(CONFIG_MIPS_AVALANCHE_LED),y)
-+obj-$(CONFIG_MIPS_AVALANCHE_LED) += avalanche_led/avalanche_led.o
-+subdir-$(CONFIG_MIPS_AVALANCHE_LED) += avalanche_led
-+endif
-+
-+ifeq ($(CONFIG_MIPS_AVALANCHE_LED),m)
-+obj-$(CONFIG_MIPS_AVALANCHE_LED) += avalanche_led/avalanche_led.o
-+subdir-$(CONFIG_MIPS_AVALANCHE_LED) += avalanche_led
-+endif
++obj-$(CONFIG_AR7_LED) += avalanche_led/avalanche_led.o
++subdir-$(CONFIG_AR7_LED) += avalanche_led
+
obj-$(CONFIG_HIL) += hp_keyb.o
obj-$(CONFIG_MAGIC_SYSRQ) += sysrq.o
obj-$(CONFIG_ATARI_DSP56K) += dsp56k.o
diff -urN linux.old/include/asm-mips/ar7/ledapp.h linux.dev/include/asm-mips/ar7/ledapp.h
--- linux.old/include/asm-mips/ar7/ledapp.h 1970-01-01 01:00:00.000000000 +0100
-+++ linux.dev/include/asm-mips/ar7/ledapp.h 2005-07-10 20:50:43.557826000 +0200
++++ linux.dev/include/asm-mips/ar7/ledapp.h 2005-07-22 06:52:42.982337272 +0200
@@ -0,0 +1,59 @@
+#ifndef __LED_APP__
+#define __LED_APP__