static int pxa250_irda_startup(struct net_device *dev)
{
__ECHO_IN;
/*
* Ensure that the ports for this device are setup correctly.
*/
set_GPIO_mode (GPIO46_STRXD_MD);
set_GPIO_mode (GPIO47_STTXD_MD);
STMCR = MCR_OUT2;
STLCR = LCR_WLS1 | LCR_WLS0;
SET_SIR_MODE;
CKEN |= CKEN5_STUART;
/* enable irq from stuart */
ICMR |= ( 1 << 20 );
/*reset FIFO*/
/* STFCR = FCR_TRFIFOE | FCR_RESETTF | FCR_RESETRF;// | FCR_ITL_16;
STIER = IER_UUE | IER_RAVIE | IER_RTOIE;
*/
__ECHO_OUT;
return 0;
}
void ezx_i2c_pm_resume(void)
{
/* enable clocks */
CKEN |= CKEN14_I2C;
set_GPIO_mode(117 | GPIO_ALT_FN_1_IN);
set_GPIO_mode(118 | GPIO_ALT_FN_1_IN);
/* enable irqs */
enable_irq(i2c_pxa_data.irq);
/* disable unit */
_ICR(adap) &= ~ICR_IUE;
/* reset the unit */
_ICR(adap) |= ICR_UR;
udelay(100);
_ICR(adap) |= ICR_FM;
/* disable unit */
_ICR(adap) &= ~ICR_IUE;
/* XXX: I2C_PXA_SLAVE_ADDR == I2C_PXA_PWR_SLAVE_ADDR ??? */
/* set our slave address */
_ISAR(adap) = I2C_PXA_SLAVE_ADDR;
/* set control register values */
_ICR(adap) = I2C_ICR_INIT;
/* set clear interrupt bits */
_ISR(adap) = I2C_ISR_INIT;
/* enable unit */
_ICR(adap) |= ICR_IUE;
udelay(100);
}
static void i2c_pxa_reset(struct i2c_algo_pxa_data *adap)
{
/* set the global I2C clocks on */
CKEN |= CKEN14_I2C;
set_GPIO_mode(117 | GPIO_ALT_FN_1_IN);
set_GPIO_mode(118 | GPIO_ALT_FN_1_IN);
#ifdef CONFIG_POWER_I2C
/* set the global PWR_I2C clock on */
CKEN |= CKEN15_PWRI2C;
/* Enable PI2C controller PWR_SCL and PWR_SDA */
PCFR |= PCFR_PI2CEN;
/* Setup GPIO3 and GPIO4 to ALT_FN1_IN (PWR_SCL and PWR_SDA) */
set_GPIO_mode(3 | GPIO_ALT_FN_1_IN);
set_GPIO_mode(4 | GPIO_ALT_FN_1_IN);
#endif
/* disable unit */
_ICR(adap) &= ~ICR_IUE;
/* reset the unit */
_ICR(adap) |= ICR_UR;
udelay(100);
_ICR(adap) |= ICR_FM;
/* disable unit */
_ICR(adap) &= ~ICR_IUE;
/* XXX: I2C_PXA_SLAVE_ADDR == I2C_PXA_PWR_SLAVE_ADDR ??? */
/* set our slave address */
_ISAR(adap) = I2C_PXA_SLAVE_ADDR;
/* set control register values */
_ICR(adap) = I2C_ICR_INIT;
/* set clear interrupt bits */
_ISR(adap) = I2C_ISR_INIT;
/* enable unit */
_ICR(adap) |= ICR_IUE;
udelay(100);
}
void turn_off_gpio(int gpio) {
set_GPIO_mode(gpio | GPIO_OUT);
GPCR(gpio) = GPIO_bit(gpio);
if (GPLR(gpio) & GPIO_bit(gpio)) {
PDEBUG("LED gpio %d on\n", gpio);
} else {
PDEBUG("LED gpio %d off\n", gpio);
}
}
ssize_t gpio_write(struct file *file, const char *ubuf, size_t count,
loff_t *offp)
{
unsigned int domode=0, inout=0, i, j;
char buf[16];
char *p;
if (count > 15) count = 15;
if (copy_from_user(buf, ubuf, count))
return -EFAULT;
buf[count] = '\0';
p = buf;
/* skip blanks: it may be all blanks, then accept it */
while (*p && isspace(*p))
p++;
if (!*p)
return count;
/* mode: accept M and I or O */
if (*p == 'm' || *p == 'M') {
domode++, p++;
if (*p == 'i' || *p == 'I')
inout= 0;
else if (*p == 'o' || *p == 'O')
inout = GPIO_MD_MASK_DIR;
else return -EINVAL;
p++;
}
/* get numbers */
if (sscanf(p, "%i=%i", &i, &j) != 2)
return -EINVAL;
if (!i || i > 80 || j > 3)
return -EINVAL;
if (!domode && j > 1)
return -EINVAL;
/* act */
if (domode) {
if (!j) domode = 0;
if (j == 1) domode = GPIO_ALT_FN_1_IN;
if (j == 2) domode = GPIO_ALT_FN_2_IN;
if (j == 3) domode = GPIO_ALT_FN_3_IN;
domode |= inout;
set_GPIO_mode( i | domode);
} else {
if (j)
GPSR(i) = GPIO_bit(i);
else
GPCR(i) = GPIO_bit(i);
}
*offp += count;
return count;
}
static void pxa250_do_fir_GPIO_config(void)
{
/*
* Modify GPIO 46 and 47 Alternate Function
*/
__ECHO_IN;
/*Switch AF*/
set_GPIO_mode (GPIO46_ICPRXD_MD);
set_GPIO_mode (GPIO47_ICPTXD_MD);
if (machine_is_lubbock())
LUB_MISC_WR |= 1 << 4;
/*init clock*/
CKEN |= CKEN13_FICP;
__ECHO_OUT;
}
/* Connect the USB device to the bus */
void udc_connect(void)
{
usbdbg("UDC connect");
#ifdef CONFIG_USB_DEV_PULLUP_GPIO
/* Turn on the USB connection by enabling the pullup resistor */
set_GPIO_mode(CONFIG_USB_DEV_PULLUP_GPIO | GPIO_OUT);
writel(GPIO_bit(CONFIG_USB_DEV_PULLUP_GPIO), GPSR(CONFIG_USB_DEV_PULLUP_GPIO));
#else
/* Host port 2 transceiver D+ pull up enable */
writel(readl(UP2OCR) | UP2OCR_DPPUE, UP2OCR);
#endif
}
static void cerf_pcmcia_reset( void)
{
int i;
// Make sure SKTSEL is 0 (single slot)
set_GPIO_mode(54 | GPIO_OUT);
GPCR1 = GPIO_bit(54);
set_GPIO_mode(GPIO54_pSKTSEL_MD);
PCMCIA_GPCR = PCMCIA_GPIO_CF_RESET_MASK;
mdelay(300);
PCMCIA_GPSR = PCMCIA_GPIO_CF_RESET_MASK;
udelay(20);
PCMCIA_GPCR = PCMCIA_GPIO_CF_RESET_MASK;
mdelay(50);
for( i=0; i<10; i++)
{
if( cerf_pcmcia_level_ready()) break;
mdelay(100);
}
}
static void __init csb226_map_io(void)
{
pxa_map_io();
iotable_init(csb226_io_desc);
/* This enables the BTUART */
CKEN |= CKEN7_BTUART;
set_GPIO_mode(GPIO42_BTRXD_MD);
set_GPIO_mode(GPIO43_BTTXD_MD);
set_GPIO_mode(GPIO44_BTCTS_MD);
set_GPIO_mode(GPIO45_BTRTS_MD);
/* This is for the CS8900 chip select */
set_GPIO_mode(GPIO78_nCS_2_MD);
/* setup sleep mode values */
PWER = 0x00000002;
PFER = 0x00000000;
PRER = 0x00000002;
PGSR0 = 0x00008000;
PGSR1 = 0x003F0202;
PGSR2 = 0x0001C000;
PCFR |= PCFR_OPDE;
}
static int pxa250_irda_set_speed(struct net_device *dev, int speed)
{
struct pxa250_irda *si = dev->priv;
int brd, ret = -EINVAL;
static int last_fir_speed=0;
__ECHO_IN;
switch (speed) {
case 9600: case 19200: case 38400:
case 57600: case 115200:
/* Baud rate fixed - Clo */
/*
* FIXME
*/
if (last_fir_speed)
{
pxa250_stop_fir(dev);
set_GPIO_mode (GPIO46_STRXD_MD);
set_GPIO_mode (GPIO47_STTXD_MD);
enable_irq(dev->irq);
netif_wake_queue(dev);
last_fir_speed=0;
}
LUB_MISC_WR &= ~(1 << 4);
brd = 14745600 / (16 * speed);
STLCR |= LCR_DLAB;
STDLH = brd >> 8; /* Clo: set Divisor Latch High */
STDLL = brd & 0xFF; /* Clo: set Devisor Latch Low */
STLCR &= ~LCR_DLAB; /* Clo: clear DLAB bit */
STMCR = MCR_OUT2;
CKEN |= CKEN5_STUART;
ICMR |= ( 1 << 20 );
STLCR = LCR_WLS1 | LCR_WLS0;
SET_SIR_MODE;
STFCR = FCR_TRFIFOE | FCR_RESETTF | FCR_RESETRF | FCR_ITL_1 ;// | FCR_ITL_16;
STIER = IER_UUE | IER_RAVIE | IER_RTIOE;
si->speed = speed;
ret = 0;
break;
case 4000000:
if (last_fir_speed)
goto speed_out;
disable_irq(dev->irq);
pxa250_sir_irda_shutdown(si);
pxa250_fir_irda_startup(si);
pxa250_irda_rx_alloc(si);
ICCR0=0;
pxa250_start_rx_dma(dev);
pxa250_ficp_rx_start();
enable_irq(si->fir_irq);
DBG("enable FIR \n");
si->speed = speed;
netif_wake_queue(dev);
last_fir_speed=1;
speed_out:
ret=0;
break;
default:
break;
}
__ECHO_OUT;
return ret;
}
int sg_ssp_init(void)
{
int result;
/* Set up owner pointers.*/
SET_MODULE_OWNER(&sg_ssp_fops);
/* Get our needed resources. */
result = check_mem_region(SG_SSP_PHYSBASE, SG_SSP_SIZE);
if (result) {
printk(KERN_INFO "sg_ssp: can't get I/O mem address 0x%lx\n",
SG_SSP_PHYSBASE);
return result;
}
request_mem_region(SG_SSP_PHYSBASE, SG_SSP_SIZE, "SSP");
result = check_mem_region(SG_GPIOCNTL_PHYSBASE, SG_GPIOCNTL_SIZE);
if (result) {
printk(KERN_INFO "sg_ssp: can't get GPIO I/O mem address 0x%lx\n",
SG_GPIOCNTL_PHYSBASE);
return result;
}
request_mem_region(SG_GPIOCNTL_PHYSBASE, SG_GPIOCNTL_SIZE, "SSPGPIO");
/* also, ioremap it */
sg_ssp_vbase = (unsigned long)sg_ssp_remap(SG_SSP_PHYSBASE,SG_SSP_SIZE);
/* Hmm... we should check the return value */
result = register_chrdev(major, "ssp", &sg_ssp_fops);
if (result < 0) {
printk(KERN_INFO "sg_ssp: can't get major number\n");
sg_ssp_unmap((void *)sg_ssp_vbase);
release_mem_region(SG_SSP_PHYSBASE,SG_SSP_SIZE);
return result;
}
if (major == 0) major = result; /* dynamic */
result = request_irq(IRQ_SSP, sg_ssp_interrupt,
SA_INTERRUPT, "ssp", NULL);
if (result) {
printk(KERN_INFO "sg_ssp: can't get assigned irq %i\n",
IRQ_SSP);
sg_ssp_unmap((void *)sg_ssp_vbase);
release_mem_region(SG_SSP_PHYSBASE,SG_SSP_SIZE);
return result;
}
SSSR = SSPS_ROR;
SSCR1 = 0;
// Enable the SSP alternate functions
set_GPIO_mode(GPIO23_SCLK_md);
set_GPIO_mode(GPIO25_STXD_MD); // Enable the SSP TX/RX lines
set_GPIO_mode(GPIO26_SRXD_MD);
set_GPIO_mode((GPIO27_SEXTCLK | GPIO_IN)); // Avoid driving the RED LED
set_GPIO_mode((22 | GPIO_OUT)); // MUX Selector
set_GPIO_mode((77 | GPIO_OUT)); // RSTN
/* Set the state of the reset pin */
GPSR(77) = GPIO_bit(77); // RSTN -> 1
return 0;
}
int
/****************************************************/
mmc_init(int verbose)
/****************************************************/
{
int retries, rc = -ENODEV;
uchar *resp;
#ifdef CONFIG_LUBBOCK
set_GPIO_mode( GPIO6_MMCCLK_MD );
set_GPIO_mode( GPIO8_MMCCS0_MD );
#endif
CKEN |= CKEN12_MMC; /* enable MMC unit clock */
mmc_csd.c_size = 0;
MMC_CLKRT = MMC_CLKRT_0_3125MHZ;
MMC_RESTO = MMC_RES_TO_MAX;
MMC_SPI = MMC_SPI_DISABLE;
/* reset */
retries = 10;
resp = mmc_cmd(0, 0, 0, 0);
resp = mmc_cmd(1, 0x00ff, 0xc000, MMC_CMDAT_INIT|MMC_CMDAT_BUSY|MMC_CMDAT_R3);
while (retries-- && resp && !(resp[4] & 0x80))
{
debug("resp %x %x\n", resp[0], resp[1]);
udelay(50);
resp = mmc_cmd(1, 0x00ff, 0xff00, MMC_CMDAT_BUSY|MMC_CMDAT_R3);
}
/* try to get card id */
resp = mmc_cmd(2, 0, 0, MMC_CMDAT_R2);
if (resp)
{
/* TODO configure mmc driver depending on card attributes */
mmc_cid_t *cid = (mmc_cid_t *)resp;
if (verbose)
{
printf("MMC found. Card desciption is:\n");
printf("Manufacturer ID = %02x%02x%02x\n",
cid->id[0], cid->id[1], cid->id[2]);
printf("HW/FW Revision = %x %x\n",cid->hwrev, cid->fwrev);
cid->hwrev = cid->fwrev = 0; /* null terminate string */
printf("Product Name = %s\n",cid->name);
printf("Serial Number = %02x%02x%02x\n",
cid->sn[0], cid->sn[1], cid->sn[2]);
printf("Month = %d\n",cid->month);
printf("Year = %d\n",1997 + cid->year);
}
/* fill in device description */
mmc_dev.if_type = IF_TYPE_MMC;
mmc_dev.dev = 0;
mmc_dev.lun = 0;
mmc_dev.type = 0;
/* FIXME fill in the correct size (is set to 32MByte) */
mmc_dev.blksz = 512;
mmc_dev.lba = 0x10000;
sprintf(mmc_dev.vendor,"Man %02x%02x%02x Snr %02x%02x%02x",
cid->id[0], cid->id[1], cid->id[2],
cid->sn[0], cid->sn[1], cid->sn[2]);
sprintf(mmc_dev.product,"%s",cid->name);
sprintf(mmc_dev.revision,"%x %x",cid->hwrev, cid->fwrev);
mmc_dev.removable = 0;
mmc_dev.block_read = mmc_bread;
/* MMC exists, get CSD too */
resp = mmc_cmd(MMC_CMD_SET_RCA, MMC_DEFAULT_RCA, 0, MMC_CMDAT_R1);
resp = mmc_cmd(MMC_CMD_SEND_CSD, MMC_DEFAULT_RCA, 0, MMC_CMDAT_R2);
if (resp)
{
mmc_csd_t *csd = (mmc_csd_t *)resp;
memcpy(&mmc_csd, csd, sizeof(csd));
rc = 0;
mmc_ready = 1;
/* FIXME add verbose printout for csd */
}
}
MMC_CLKRT = 0; /* 20 MHz */
resp = mmc_cmd(7, MMC_DEFAULT_RCA, 0, MMC_CMDAT_R1);
fat_register_device(&mmc_dev,1); /* partitions start counting with 1 */
return rc;
}
static int ezx_i2c_pm_callback(struct pm_dev *pm_dev, pm_request_t req, void *data)
{
switch(req)
{
case PM_SUSPEND:
/* disable IRQs */
if (i2c_pxa_data.irq)
disable_irq(i2c_pxa_data.irq);
/* disable PI2C Controller */
PCFR &= ~PCFR_PI2CEN;
/* disable clocks */
CKEN &= ~CKEN14_I2C;
#ifdef CONFIG_POWER_I2C
if (i2c_pxa_pwr_data.irq)
disable_irq(i2c_pxa_pwr_data.irq);
/* disable PI2C Controller */
PCFR &= ~PCFR_PI2CEN;
CKEN &= ~CKEN15_PWRI2C;
#endif
break;
case PM_RESUME:
/* enable clocks */
CKEN |= CKEN14_I2C;
set_GPIO_mode(117 | GPIO_ALT_FN_1_IN);
set_GPIO_mode(118 | GPIO_ALT_FN_1_IN);
/* enable irqs */
enable_irq(i2c_pxa_data.irq);
#ifdef CONFIG_POWER_I2C
/* set the global PWR_I2C clock on */
CKEN |= CKEN15_PWRI2C;
/* Enable PI2C controller PWR_SCL and PWR_SDA */
PCFR |= PCFR_PI2CEN;
set_GPIO_mode(3 | GPIO_ALT_FN_1_IN);
set_GPIO_mode(4 | GPIO_ALT_FN_1_IN);
enable_irq(i2c_pxa_pwr_data.irq);
#endif
/* disable unit */
_ICR(adap) &= ~ICR_IUE;
/* reset the unit */
_ICR(adap) |= ICR_UR;
udelay(100);
_ICR(adap) |= ICR_FM;
/* disable unit */
_ICR(adap) &= ~ICR_IUE;
/* XXX: I2C_PXA_SLAVE_ADDR == I2C_PXA_PWR_SLAVE_ADDR ??? */
/* set our slave address */
_ISAR(adap) = I2C_PXA_SLAVE_ADDR;
/* set control register values */
_ICR(adap) = I2C_ICR_INIT;
/* set clear interrupt bits */
_ISR(adap) = I2C_ISR_INIT;
/* enable unit */
_ICR(adap) |= ICR_IUE;
udelay(100);
break;
}
return 0;
}
static int __init s3c2410_ts_init(void)
{
int ret;
tsEvent = tsEvent_dummy;
ret = register_chrdev(0, DEVICE_NAME, &s3c2410_fops);
if (ret < 0) {
printk(DEVICE_NAME " can't get major number\n");
return ret;
}
tsMajor = ret;
/* set gpio to XP, YM, YP and YM */
#if 0
set_GPIO_mode(GPIO106_nYPON_MD);
set_GPIO_mode(GPIO105_YMON_MD);
set_GPIO_mode(GPIO104_nXPON_MD);
set_GPIO_mode(GPIO103_XMON_MD);
GPUP(GPIO106_nYPON) |= GPIO_bit(GPIO106_nYPON);
GPUP(GPIO105_YMON) &= GPIO_bit(GPIO105_YMON);
GPUP(GPIO104_nXPON) |= GPIO_bit(GPIO104_nXPON);
GPUP(GPIO103_XMON) &= GPIO_bit(GPIO103_XMON);
#else
set_gpio_ctrl(GPIO_YPON);
set_gpio_ctrl(GPIO_YMON);
set_gpio_ctrl(GPIO_XPON);
set_gpio_ctrl(GPIO_XMON);
#endif
/* Enable touch interrupt */
ret = request_irq(IRQ_ADC_DONE, s3c2410_isr_adc, SA_INTERRUPT,
DEVICE_NAME, s3c2410_isr_adc);
if (ret) goto adc_failed;
ret = request_irq(IRQ_TC, s3c2410_isr_tc, SA_INTERRUPT,
DEVICE_NAME, s3c2410_isr_tc);
if (ret) goto tc_failed;
/* Wait for touch screen interrupts */
wait_down_int();
#ifdef CONFIG_DEVFS_FS
devfs_ts_dir = devfs_mk_dir(NULL, "touchscreen", NULL);
devfs_tsraw = devfs_register(devfs_ts_dir, "0raw", DEVFS_FL_DEFAULT,
tsMajor, TSRAW_MINOR, S_IFCHR | S_IRUSR | S_IWUSR,
&s3c2410_fops, NULL);
#endif
#ifdef CONFIG_PM
#if 0
tsdev.pm_dev = pm_register(PM_GP_DEV, PM_USER_INPUT,
s3c2410_ts_pm_callback);
#endif
tsdev.pm_dev = pm_register(PM_DEBUG_DEV, PM_USER_INPUT,
s3c2410_ts_pm_callback);
#endif
printk(DEVICE_NAME " initialized\n");
return 0;
tc_failed:
free_irq(IRQ_ADC_DONE, s3c2410_isr_adc);
adc_failed:
return ret;
}
static int do_ioctl(struct inode * inode, struct file *filp,
u_int cmd, u_long arg)
{
struct apm_user * as;
struct pm_dev * pm;
struct ipm_config conf;
as = filp->private_data;
if (check_apm_user(as, "ioctl"))
return -EIO;
memset(&conf, 0, sizeof(conf));
switch (cmd) {
case APM_IOC_SUSPEND:
pm_do_suspend(CPUMODE_SLEEP);
break;
case APM_IOC_SET_WAKEUP:
if ((pm = pm_find((pm_dev_t)arg,NULL)) == NULL)
return -EINVAL;
pm_send(pm,PM_SET_WAKEUP,NULL);
break;
case APM_IOC_SLEEP:
pm_go_sleep(arg);
break;
case APM_IOC_SET_SPROF_WIN:
sleep_to = arg * HZ;
APM_DPRINTK("do_ioctl: sleep timeout %ld\n", arg);
break;
case APM_IOC_WAKEUP_ENABLE:
PWER |= arg;
APM_DPRINTK("do_ioctl: enable wakeup source:PWER=0x%x\n", PWER);
break;
case APM_IOC_WAKEUP_DISABLE:
PWER &= ~arg;
APM_DPRINTK("do_ioctl: disable wakeup source:PWER=0x%x\n", PWER);
break;
case APM_IOC_POWEROFF:
APM_DPRINTK("do_ioctl: do power off\n");
/* here all device should response ok */
pm_send_all(PM_SUSPEND, (void *)3);
pm_do_poweroff();
pm_send_all(PM_RESUME, (void *)0);
break;
case APM_IOC_RESET_BP:
APM_DPRINTK("do_ioctl: reset bp\n");
GPCR(GPIO_BB_RESET) = GPIO_bit(GPIO_BB_RESET);
mdelay(1);
GPSR(GPIO_BB_RESET) = GPIO_bit(GPIO_BB_RESET);
break;
case APM_IOC_USEROFF_ENABLE:
APM_DPRINTK("do_ioctl: useroff support enable\n");
user_off_available = (int)arg;
break;
case APM_IOC_NOTIFY_BP:
break;
case APM_IOC_REFLASH:
cpu_proc_fin();
*(unsigned long *)(phys_to_virt(FLAG_ADDR)) = REFLASH_FLAG;
// power_ic_periph_set_usb_pull_up(0);
//LIN mdelay(1000);
//LIN let GPIO control the connectivity
#include <linux/power_ic.h>
set_GPIO_mode(GPIO_USB_READY|GPIO_OUT);
clr_GPIO(GPIO_USB_READY);
power_ic_periph_set_usb_pull_up(0);
mdelay(10);
power_ic_set_reg_bit(POWER_IC_REG_EOC_CONN_CONTROL,19,1);//LIN set USB_CNTRL(bit19) to disable emu control
mdelay(1000);
//LIN power_ic_periph_set_usb_pull_up(1);
/* Initialize the watchdog and let it fire */
OWER = OWER_WME;
OSSR = OSSR_M3;
OSMR3 = OSCR + CLOCK_TICK_RATE/100; /* ... in 10 ms */
MDREFR |= MDREFR_SLFRSH;
while(1);
break;
case APM_IOC_PASSTHRU:
cpu_proc_fin();
*(unsigned long *)(phys_to_virt(FLAG_ADDR)) = PASS_THRU_FLAG;
power_ic_periph_set_usb_pull_up(0);
mdelay(1000);
power_ic_periph_set_usb_pull_up(1);
/* Initialize the watchdog and let it fire */
OWER = OWER_WME;
OSSR = OSSR_M3;
OSMR3 = OSCR + CLOCK_TICK_RATE/100; /* ... in 10 ms */
MDREFR |= MDREFR_SLFRSH;
while(1);
break;
case APM_IOC_SET_IPROF_WIN:
/* set profile window size */
break;
case APM_IOC_STARTPMU:
if( pipm_start_pmu !=NULL )
pipm_start_pmu();
break;
case APM_IOC_GET_IPM_CONFIG:
get_ipm_config(&conf);
return (copy_to_user((void *)arg, &conf,sizeof(conf)))? -EFAULT:0;
break;
case APM_IOC_SET_IPM_CONFIG:
if(copy_from_user(&conf,(void *)arg,sizeof(conf)))
return -EFAULT;
return set_ipm_config(&conf);
break;
default:
return -EINVAL;
}
return 0;
}
static void usb_hub_port_connect_change(struct usb_hub *hubstate, int port,
u16 portstatus, u16 portchange)
{
struct usb_device *hub = hubstate->dev;
struct usb_device *dev;
unsigned int delay = HUB_SHORT_RESET_TIME;
int i;
dbg("port %d, portstatus %x, change %x, %s",
port + 1, portstatus, portchange, portspeed (portstatus));
/* Clear the connection change status */
usb_clear_port_feature(hub, port + 1, USB_PORT_FEAT_C_CONNECTION);
/* Disconnect any existing devices under this port */
if (hub->children[port])
usb_disconnect(&hub->children[port]);
/* Return now if nothing is connected */
if (!(portstatus & USB_PORT_STAT_CONNECTION)) {
if (portstatus & USB_PORT_STAT_ENABLE)
usb_hub_port_disable(hub, port);
return;
}
if (usb_hub_port_debounce(hub, port)) {
err("connect-debounce failed, port %d disabled", port+1);
usb_hub_port_disable(hub, port);
return;
}
down(&usb_address0_sem);
for (i = 0; i < HUB_PROBE_TRIES; i++) {
struct usb_device *pdev;
int len;
/* Allocate a new device struct */
dev = usb_alloc_dev(hub, hub->bus);
if (!dev) {
err("couldn't allocate usb_device");
break;
}
hub->children[port] = dev;
/* add by Levis for wakeup BP */
int begin = 0;
#ifdef CONFIG_ARCH_EZXBASE
set_GPIO_mode(GPIO_IN | GPIO_BP_RDY);
if(!GPIO_is_high(GPIO_BP_RDY))
{
if(GPIO_is_high(GPIO_AP_RDY ))
{
GPCR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
udelay(WAKE_UP_BP_UDELAY);
GPSR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
}else {
GPSR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
udelay(WAKE_UP_BP_UDELAY);
GPCR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
}
begin = jiffies;
while(!GPIO_is_high(GPIO_BP_RDY) && (jiffies < (begin+HZ))) ;
if(!GPIO_is_high(GPIO_BP_RDY))
{
printk("%s: Wakeup BP timeout! BP is still in sleep state!\n", __FUNCTION__);
}
}
#else
set_GPIO_mode(GPIO_IN | 41);
if(GPIO_is_high(41))
{
if(GPIO_is_high(GPIO_MCU_INT_SW))
GPCR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
else {
GPSR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
}
begin = jiffies;
while(GPIO_is_high(41) && (jiffies < (begin+HZ))) printk("%s: waitting for BP active!\n", __FUNCTION__);
if(GPIO_is_high(GPIO_MCU_INT_SW))
GPCR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
else {
GPSR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
}
}
#endif
/* end Levis */
/* Reset the device */
if (usb_hub_port_reset(hub, port, dev, delay)) {
usb_free_dev(dev);
break;
}
/* Find a new device ID for it */
usb_connect(dev);
/* Set up TT records, if needed */
if (hub->tt) {
dev->tt = hub->tt;
dev->ttport = hub->ttport;
} else if (dev->speed != USB_SPEED_HIGH
&& hub->speed == USB_SPEED_HIGH) {
dev->tt = &hubstate->tt;
dev->ttport = port + 1;
}
/* Save readable and stable topology id, distinguishing
* devices by location for diagnostics, tools, etc. The
* string is a path along hub ports, from the root. Each
* device's id will be stable until USB is re-cabled, and
* hubs are often labeled with these port numbers.
*
* Initial size: ".NN" times five hubs + NUL = 16 bytes max
* (quite rare, since most hubs have 4-6 ports).
*/
pdev = dev->parent;
if (pdev->devpath [0] != '0') /* parent not root? */
len = snprintf (dev->devpath, sizeof dev->devpath,
"%s.%d", pdev->devpath, port + 1);
/* root == "0", root port 2 == "2", port 3 that hub "2.3" */
else
len = snprintf (dev->devpath, sizeof dev->devpath,
"%d", port + 1);
if (len == sizeof dev->devpath)
warn ("devpath size! usb/%03d/%03d path %s",
dev->bus->busnum, dev->devnum, dev->devpath);
info("new USB device %s-%s, assigned address %d",
dev->bus->bus_name, dev->devpath, dev->devnum);
/* Run it through the hoops (find a driver, etc) */
if (!usb_new_device(dev))
goto done;
/* Free the configuration if there was an error */
usb_free_dev(dev);
/* Switch to a long reset time */
delay = HUB_LONG_RESET_TIME;
}
hub->children[port] = NULL;
usb_hub_port_disable(hub, port);
done:
up(&usb_address0_sem);
}
static void ipcusb_xmit_data(void)
{
int c, count = IPC_URB_SIZE;
int result = 0;
int buf_flag = 0;
int buf_num = 0;
if( !(UHCRHPS3 & 0x2))
{
printk("\n ipcusb_xmit_data:port has been disabled.\n");
return;
}
//printk("%s: sumbit_times=%d, callback_times=%d\n", __FUNCTION__, sumbit_times, callback_times);
if(bvd_ipc->write_finished_flag == 0)
{
//printk("%s: write_finished_flag=%d, return!\n", __FUNCTION__, bvd_ipc->write_finished_flag);
return;
}
while (1)
{
c = CIRC_CNT_TO_END(bvd_ipc->xmit.head, bvd_ipc->xmit.tail, IPC_USB_XMIT_SIZE);
if (count < c)
c = count;
if (c <= 0) {
break;
}
memcpy(bvd_ipc->obuf+buf_num, bvd_ipc->xmit.buf + bvd_ipc->xmit.tail, c);
buf_flag = 1;
bvd_ipc->xmit.tail = ((bvd_ipc->xmit.tail + c) & (IPC_USB_XMIT_SIZE-1));
count -= c;
buf_num += c;
}
#ifdef CONFIG_NO_USB_SUSPEND_RESUME
#else
if(buf_num == 0)
{
bvd_dbg("ipcusb_xmit_data: buf_num=%d, add suspend_timer", buf_num);
bvd_ipc->suspend_flag = 0;
mod_timer(&suspend_timer, jiffies+(IPC_USB_SUSPEND_INTERVAL*HZ/1000));
}
#endif
bvd_dbg("ipcusb_xmit_data: buf_num=%d", buf_num);
bvd_dbg("ipcusb_xmit_data: bvd_ipc->obuf: ");
#ifdef BVD_DEBUG
bvd_dbg_hex((bvd_ipc->obuf)-buf_num, buf_num);
#endif
if( buf_flag )
{
bvd_ipc->writeurb_mux.transfer_buffer_length = buf_num;
bvd_dbg("ipcusb_xmit_data: copy data to write urb finished! ");
#ifdef CONFIG_NO_USB_SUSPEND_RESUME
#else
if((UHCRHPS3 & 0x4) == 0x4)
{
static int ret;
int time = 0;
#ifdef CONFIG_ARCH_EZXBASE
/**if BP sleep, wake up BP first**/
set_GPIO_mode(GPIO_IN | GPIO_BP_RDY);
if(!GPIO_is_high(GPIO_BP_RDY))
{
if(GPIO_is_high(GPIO_AP_RDY ))
{
GPCR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
udelay(WAKE_UP_BP_UDELAY);
GPSR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
}else {
GPSR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
udelay(WAKE_UP_BP_UDELAY);
GPCR(GPIO_AP_RDY ) = GPIO_bit(GPIO_AP_RDY );
}
time = jiffies;
while(!GPIO_is_high(GPIO_BP_RDY) && (jiffies < (time+HZ))) ;
if(!GPIO_is_high(GPIO_BP_RDY))
{
printk("%s: Wakeup BP timeout! BP is still in sleep state!\n", __FUNCTION__);
}
}
#else
/**if BP sleep, wake up BP first**/
set_GPIO_mode(GPIO_IN | 41);
if(GPIO_is_high(41))
{
if(GPIO_is_high(GPIO_MCU_INT_SW))
GPCR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
else{
GPSR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
}
time = jiffies;
while(GPIO_is_high(41) && (jiffies < (time+HZ))) ;
if(GPIO_is_high(41))
{
printk("%s: Wakeup BP timeout! BP state is %d\n", __FUNCTION__, GPIO_is_high(41));
}
if(GPIO_is_high(GPIO_MCU_INT_SW))
GPCR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
else{
GPSR(GPIO_MCU_INT_SW) = GPIO_bit(GPIO_MCU_INT_SW);
}
}
#endif
/** Resume BP**/
// ipc_traffic = 1;
UHCRHPS3 = 0x8;
while(!(UHCRHPS3 & (1<<18))) mdelay(1);
UHCRHPS3 = 1<<18; // Write 1 to clear
bvd_dbg("ipc-resume[0x%x]\n",UHCRHPS3);
bvd_dbg("ipcusb_xmit_data: Send RESUME signal! UHCRHPS3=0x%x\n", UHCRHPS3);
host_port_suspended = 0;
mdelay(3);
set_BLE();
/*send IN token*/
bvd_ipc->readurb_mux.actual_length = 0;
bvd_ipc->readurb_mux.dev = bvd_ipc->ipc_dev;
if((ret = usb_submit_urb(&bvd_ipc->readurb_mux)) < 0)
{
warn("\nerr:[out]submit_readurb failed [%d]\n", ret);
}
bvd_dbg("\n[out]IN token sent-----\n");
}
#endif
sumbit_times++;
bvd_ipc->write_finished_flag = 0;
bvd_dbg("%s: clear write_finished_flag:%d\n", __FUNCTION__, bvd_ipc->write_finished_flag);
bvd_ipc->writeurb_mux.dev = bvd_ipc->ipc_dev;
if((result = usb_submit_urb(&bvd_ipc->writeurb_mux)) < 0)
{
warn("\n[out]submit_urb_ret[%d]\n", result);
}
bvd_dbg("\n[out]usb_submit_urb[%d]\n", result);
}
}
/* pxa_pcmcia_driver_init()
* ^^^^^^^^^^^^^^^^^^^^^^^^^^^
*
* This routine performs a basic sanity check to ensure that this
* kernel has been built with the appropriate board-specific low-level
* PCMCIA support, performs low-level PCMCIA initialization, registers
* this socket driver with Card Services, and then spawns the daemon
* thread which is the real workhorse of the socket driver.
*
* Please see linux/Documentation/arm/SA1100/PCMCIA for more information
* on the low-level kernel interface.
*
* Returns: 0 on success, -1 on error
*/
static int __init pxa_pcmcia_driver_init(void){
servinfo_t info;
struct pcmcia_init pcmcia_init;
struct pcmcia_state state[PXA_PCMCIA_MAX_SOCK];
struct pcmcia_state_array state_array;
unsigned int i, clock;
unsigned long mecr;
printk(KERN_INFO "Intel PXA250/210 PCMCIA (CS release %s)\n", CS_RELEASE);
CardServices(GetCardServicesInfo, &info);
if(info.Revision!=CS_RELEASE_CODE){
printk(KERN_ERR "Card Services release codes do not match\n");
return -1;
}
/* Setup GPIOs for PCMCIA/CF alternate function mode.
*
* It would be nice if set_GPIO_mode included support
* for driving GPIO outputs to default high/low state
* before programming GPIOs as outputs. Setting GPIO
* outputs to default high/low state via GPSR/GPCR
* before defining them as outputs should reduce
* the possibility of glitching outputs during GPIO
* setup. This of course assumes external terminators
* are present to hold GPIOs in a defined state.
*
* In the meantime, setup default state of GPIO
* outputs before we enable them as outputs.
*/
GPSR(GPIO48_nPOE) = GPIO_bit(GPIO48_nPOE) |
GPIO_bit(GPIO49_nPWE) |
GPIO_bit(GPIO50_nPIOR) |
GPIO_bit(GPIO51_nPIOW) |
GPIO_bit(GPIO52_nPCE_1) |
GPIO_bit(GPIO53_nPCE_2);
set_GPIO_mode(GPIO48_nPOE_MD);
set_GPIO_mode(GPIO49_nPWE_MD);
set_GPIO_mode(GPIO50_nPIOR_MD);
set_GPIO_mode(GPIO51_nPIOW_MD);
set_GPIO_mode(GPIO52_nPCE_1_MD);
set_GPIO_mode(GPIO53_nPCE_2_MD);
set_GPIO_mode(GPIO54_pSKTSEL_MD); /* REVISIT: s/b dependent on num sockets */
set_GPIO_mode(GPIO55_nPREG_MD);
set_GPIO_mode(GPIO56_nPWAIT_MD);
set_GPIO_mode(GPIO57_nIOIS16_MD);
if(machine_is_lubbock()){
#ifdef CONFIG_ARCH_LUBBOCK
pcmcia_low_level=&lubbock_pcmcia_ops;
#endif
} else if (machine_is_pxa_idp()) {
pcmcia_low_level=&pxa_idp_pcmcia_ops;
} else if( machine_is_pxa_cerf()){
pcmcia_low_level=&cerf_pcmcia_ops;
}
if (!pcmcia_low_level) {
printk(KERN_ERR "This hardware is not supported by the PXA250/210 Card Service driver\n");
return -ENODEV;
}
pcmcia_init.handler=pxa_pcmcia_interrupt;
if((pxa_pcmcia_socket_count=pcmcia_low_level->init(&pcmcia_init))<0){
printk(KERN_ERR "Unable to initialize kernel PCMCIA service.\n");
return -EIO;
}
state_array.size=pxa_pcmcia_socket_count;
state_array.state=state;
/* Configure MECR based on the number of sockets present. */
if (pxa_pcmcia_socket_count == 2) {
MECR |= GPIO_bit(0);
} else {
MECR &= ~GPIO_bit(0);
}
if(pcmcia_low_level->socket_state(&state_array)<0){
printk(KERN_ERR "Unable to get PCMCIA status from kernel.\n");
return -EIO;
}
/* Well, it looks good to go. So we can now enable the PCMCIA
* controller.
*/
MECR |= GPIO_bit(1);
/* We need to initialize the MCXX registers to default values
* here because we're not guaranteed to see a SetIOMap operation
* at runtime.
*/
clock = get_lclk_frequency_10khz();
for(i=0; i<pxa_pcmcia_socket_count; ++i){
pxa_pcmcia_socket[i].k_state=state[i];
/* This is an interim fix. Apparently, SetSocket is no longer
* called to initialize each socket (prior to the first detect
* event). For now, we'll just manually set up the mask.
*/
pxa_pcmcia_socket[i].cs_state.csc_mask=SS_DETECT;
pxa_pcmcia_socket[i].virt_io=(i==0)?PCMCIA_IO_0_BASE:PCMCIA_IO_1_BASE;
pxa_pcmcia_socket[i].phys_attr=_PCMCIAAttr(i);
pxa_pcmcia_socket[i].phys_mem=_PCMCIAMem(i);
/* REVISIT: cleanup these macros */
//MCIO_SET(i, PXA_PCMCIA_IO_ACCESS, clock);
//MCATTR_SET(i, PXA_PCMCIA_5V_MEM_ACCESS, clock);
//MCMEM_SET(i, PXA_PCMCIA_5V_MEM_ACCESS, clock);
pxa_pcmcia_socket[i].speed_io=PXA_PCMCIA_IO_ACCESS;
pxa_pcmcia_socket[i].speed_attr=PXA_PCMCIA_5V_MEM_ACCESS;
pxa_pcmcia_socket[i].speed_mem=PXA_PCMCIA_5V_MEM_ACCESS;
}
/* REVISIT: cleanup these macros */
MCMEM0 = ((pxa_mcxx_setup(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_SETUP_MASK) << MCXX_SETUP_SHIFT)
| ((pxa_mcxx_asst(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_ASST_MASK) << MCXX_ASST_SHIFT)
| ((pxa_mcxx_hold(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_HOLD_MASK) << MCXX_HOLD_SHIFT);
MCMEM1 = ((pxa_mcxx_setup(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_SETUP_MASK) << MCXX_SETUP_SHIFT)
| ((pxa_mcxx_asst(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_ASST_MASK) << MCXX_ASST_SHIFT)
| ((pxa_mcxx_hold(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_HOLD_MASK) << MCXX_HOLD_SHIFT);
MCATT0 = ((pxa_mcxx_setup(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_SETUP_MASK) << MCXX_SETUP_SHIFT)
| ((pxa_mcxx_asst(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_ASST_MASK) << MCXX_ASST_SHIFT)
| ((pxa_mcxx_hold(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_HOLD_MASK) << MCXX_HOLD_SHIFT);
MCATT1 = ((pxa_mcxx_setup(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_SETUP_MASK) << MCXX_SETUP_SHIFT)
| ((pxa_mcxx_asst(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_ASST_MASK) << MCXX_ASST_SHIFT)
| ((pxa_mcxx_hold(PXA_PCMCIA_5V_MEM_ACCESS, clock)
& MCXX_HOLD_MASK) << MCXX_HOLD_SHIFT);
MCIO0 = ((pxa_mcxx_setup(PXA_PCMCIA_IO_ACCESS, clock)
& MCXX_SETUP_MASK) << MCXX_SETUP_SHIFT)
| ((pxa_mcxx_asst(PXA_PCMCIA_IO_ACCESS, clock)
& MCXX_ASST_MASK) << MCXX_ASST_SHIFT)
| ((pxa_mcxx_hold(PXA_PCMCIA_IO_ACCESS, clock)
& MCXX_HOLD_MASK) << MCXX_HOLD_SHIFT);
MCIO1 = ((pxa_mcxx_setup(PXA_PCMCIA_IO_ACCESS, clock)
& MCXX_SETUP_MASK) << MCXX_SETUP_SHIFT)
| ((pxa_mcxx_asst(PXA_PCMCIA_IO_ACCESS, clock)
& MCXX_ASST_MASK) << MCXX_ASST_SHIFT)
| ((pxa_mcxx_hold(PXA_PCMCIA_IO_ACCESS, clock)
& MCXX_HOLD_MASK) << MCXX_HOLD_SHIFT);
#ifdef CONFIG_CPU_FREQ
if(cpufreq_register_notifier(&pxa_pcmcia_notifier_block) < 0){
printk(KERN_ERR "Unable to register CPU frequency change notifier\n");
return -ENXIO;
}
#endif
/* Only advertise as many sockets as we can detect: */
if(register_ss_entry(pxa_pcmcia_socket_count,
&pxa_pcmcia_operations)<0){
printk(KERN_ERR "Unable to register socket service routine\n");
return -ENXIO;
}
/* Start the event poll timer. It will reschedule by itself afterwards. */
pxa_pcmcia_poll_event(0);
DEBUG(1, "pxa_cs: initialization complete\n");
return 0;
} /* pxa_pcmcia_driver_init() */
/*----------------------------------------------------------------------------*/
static void
initTrig (void)
{
set_GPIO_mode(GPIO40_FFDTR | GPIO_OUT);
clearTrig();
}/* end of initTrig() */
